T Trilobites of New York
A N
I L L U S T R A T E D
Thomas E. Whiteley Gerald J. Kloc Carlton E. Brett with a forewo...
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T Trilobites of New York
A N
I L L U S T R A T E D
Thomas E. Whiteley Gerald J. Kloc Carlton E. Brett with a foreword by Rolf Ludvigsen
Published in cooperation Paleontological Research
COMSTOCK
with
Institution,
PUBLISHING
CORNELL
UNIVERSITY
Ithaca
London
and
the Ithaca,
New
York
A S S O C I A T E S , a division o f
PRESS
G U I D E
C o p y r i g h t © 2002 by Cornell University
All rights r e s e r v e d . Except for brief quotations in a review, this book, or parts thereof, must not be r e p r o d u c e d in any form without permission in writing from the publisher. For information a d d r e s s Cornell University Press, Sage House, 512 East State Street, Ithaca, N e w York 14850.
First p u b l i s h e d 2 0 0 2 by Cornell University Press Published in c o o p e r a t i o n with the Paleontological Research Institution, Ithaca, N e w York
Printed in the United States of A m e r i c a
Library of C o n g r e s s Cataloging-in-Publication Data Whiteley, T h o m a s E. ( T h o m a s Edward), 1 9 3 2 Trilobites of N e w York : an illustrated guide / Thomas E. Whiteley, G e r a l d J. Kloc, a n d Carlton E. Brett, p.
cm.
Includes b i b l i o g r a p h i c a l references and index. ISBN 0-8014-3969-9 (acid-free paper) 1. Trilobites—New York (State)
I. Kloc, Gerald J.
II. Brett, Carlton E. (Carlton Elliot)
III. Paleontological
Research Institution (Ithaca, N.Y.)
IV. Title.
QE821 .W397
2002
565'.39'09747—dc21 2001054767
Cornell University Press strives to use environmentally r e s p o n s i b l e suppliers a n d materials to the fullest extent possible in the p u b l i s h i n g of its b o o k s . Such materials include v e g e t a b l e - b a s e d , low-VOC inks a n d acid-free papers that are r e c y c l e d , totally chlorine-free, or partly c o m p o s e d of n o n w o o d fibers. For further information, visit our website at www.cornellpress.cornell.edu.
Cloth printing
10
9 8 7 6 5 4 3 2 1
Contents
Text Figures vii
Chapter
Text Tables ix
THE
Foreword xi
NEW YORK
Preface xv
4
PALEOZOIC
GEOLOGY
OF 43
Overview 4 3 C a m b r i a n Period 4 6
Chapter
1
Ordovician Period 1
BACKGROUND INFORMATION
Silurian Period 81 D e v o n i a n Period
Historical Notes 1
56
95
Trilobite Names 2
Chapter Chapter
2
THE T R I L O B I T E S 4
THE B I O L O G Y OF T R I L O B I T E S Exoskeleton Ontogeny
5
117
O r d e r Redlichiida
4
118
Order Corynexochida
13
Soft B o d y Parts
O r d e r Agnostida
117
O r d e r Lichida
17
124
Order Phacopida
L i f e - M o d e 21
O r d e r Proetida Evolution and Cladistics 30
O r d e r Asaphida
128 148 157
O r d e r Ptychopariida
Chapter
118
163
3 32
TAPHONOMY
Appendix A: Trilobites and T h e i r E n v i r o n m e n t s
Death, Decay, and Disarticulation 32
Appendix B : T h e P h o t o g r a p h y
Transport and Reorientation
Glossary
35
172
Fragmentation and Biased Preservation 36
References
Abrasion, C o r r o s i o n , and E n c r u s t a t i o n
Trilobite Index
37
Fossil Diagenesis: G e o c h e m i c a l Processing of Potential Fossils 37
168
170
177 191
Index 201 Plates
204
Trilobite Taphofacies 4 0 Trilobite Lagerstatten
40
v
Text Figures
2.1
Trilobite structure using Eldredgeops rami using Kettneraspis
5
2.2
Trilobite structure
2.3
T h e structure of the trilobite c e p h a l o n using Calymene species
tubercidata
6
2.4
Trilobite eyes 9
2.5
Cephalic sutures 9
2.6
Hxoskeletal pits or circular perforations
2.7
Ventral a n a t o m y of the exoskeleton
2.8
O n t o g e n y of the trilobite
2.9
Trilobite exoskeletons with attached fauna or injury
2.10
Trilobite appendage reconstruction and n o m e n c l a t u r e
2.11
Ventral a n a t o m y and appendages 20
8
11
12
14
2.12
Internal a n a t o m y of the trilobite 22
2.13
Trilobite shapes and functions 23
18 19
2.14
Trilobite traces 25
2.15
Trilobite injuries 27
2.16
Cryptolithus, the most-studied trilobite genus f o u n d in New York
3.1
fossil assemblages reflecting various c o n d i t i o n s and t i m i n g of burial
3.2
C o n d i t i o n s for the f o r m a t i o n of pyritized, well-preserved fossils 39
28 34
4.1
T i m e scale for Earth history and for the Paleozoic rocks in New York 44
4.2
P r e c a m b r i a n Grenville ( 1 . 0 B P ) m e t a m o r p h i c / i g n e o u s rocks 4 6
4.3
M a p showing the extent of the Grenville belt in eastern N o r t h A m e r i c a 47
4.4
Paleomagnetic reconstruction of the supercontinenl Rodinia
4.5
Position of the Laurentian plate and n e i g h b o r i n g Baltica and Avalonia
48
terranes from the C a m b r i a n to the Devonian 49 4.6
C a m b r i a n rocks in New York 50
4.7
New York in the C a m b r i a n 52
4.8
C l o s e - u p o f Upper C a m b r i a n Potsdam S a n d s t o n e 5 3
4.9
Upper C a m b r i a n limestones 54
4.10
Simplified stratigraphy of the C a m b r i a n - O r d o v i c i a n rocks in the T a c o n i c allochthon
55
4.11
Lower C a m b r i a n a l l o c h t h o n o u s beds of the low T a c o n i c M o u n t a i n s
4.12
Stratigraphic chart of the Ordovician exposures in New York 57
56
4 . 1 3 A - C New York during the Early and early M i d d l e O r d o v i c i a n 58 4.13D-F
New York during the Middle O r d o v i c i a n 59
4.14
Details of the stratigraphy of the Chazy G r o u p in northeastern New York 63
4.15
Flute casts on Austin Glen graywacke 65
4.16
Black River limestones 66
4.17
Middle Ordovician Black River G r o u p 67
4.18
Close-up o f sharp Black River/Trenton ( W a t e r t o w n - N a p a n e e ) c o n t a c t 6 8
4.19
Close-up of storm beds in the Middle Ordovician Kings Falls L i m e s t o n e 69
viii
TEXT 4.20
M a p s of New York during late Middle Ordovician times 70
4.21
M i d d l e Trenton at Trenton Falls 72
4.22
M i d d l e Ordovician Trenton G r o u p limestone 7 3
4.23
Trenton at Trenton Falls 74
FIGURES
4.24
M i d d l e O r d o v i c i a n Dolgeville and Utica rocks 77
4.25
New York maps during the late M i d d l e Ordovician and the Upper
4.26
Ordovician/Silurian u n c o n f o r m i t i e s
4.27
Stratigraphic chart of the Silurian rocks in New York 82
4.28
O r d o v i c i a n - S i l u r i a n ( C h e r o k e e ) u n c o n f o r m i t y / O r d o v i c i a n - L o w e r Silurian
4.29
M a p s o f New York during W e n l o c k times
4.30
I r o n d e q u o i t - R o c h e s t e r b i o h e r m at the upper part of the Lower Silurian
Ordovician
succession
79 81
84
Clinton Group
87
88
4.31
M i d Silurian successions 91
4.32
Silurian c a r b o n a t e s 92
4.33
D o m a l stromatolites
4.34
C o m p o s i t e stratigraphic chart for the n o r t h e r n and central parts of the
4.35
N e w York during the Early D e v o n i a n 97
Appalachian Basin
94
96
4.36
Upper Silurian/Lower Devonian rocks
4.37
New York during the early M i d d l e D e v o n i a n
99
4.38
Upper Silurian/Onondaga Limestone
103
104
4.39
M i d d l e D e v o n i a n rocks
4.40
New York d u r i n g the Middle D e v o n i a n H a m i l t o n deposition
4.41
Devonian successions
4.42
M i d d l e D e v o n i a n / U p p e r Devonian successions
4.43
Stratigraphy of the Upper Devonian and the upper Middle Devonian of New
5.1
Lichids from the lower and lowest M i d d l e Devonian of New York
125
5.2
Key cephalic differences between D a l m a n i t i d a e and Synphoriidae
136
5.3
Trilobites of the families D a l m a n i t i d a e and Synphoriidae
5.4
Lower D e v o n i a n and lower Middle Devonian p h a c o p i n s
5.5
Features of New York Cryptolithus
York
106 108
113 114
115
164
138 143
Text Tables
5.1
Trilobites of the suborder Agnostina
118
5.2
Trilobites of the suborder Eodiscina
119
5.3
Defining features of the New York asteropygins
5.4
Features of the genera Bellacartwrightia and
129
5.5
Features of the Lower Devonian phacopids f r o m New York
5.6
Features of the Middle Devonian phacopids of New York
5.7
Features of the genus Odontocephalus of New York
5.8
Features of the described proetids of New York
Greenops
153
130
147
141 142
Foreword
T o m Whiteley, a n accomplished a m a t e u r paleontologist, has
" l o v e r " ) are those who pursue an activity out of interest instead
taken the lead in c o m p i l i n g a m u c h - n e e d e d popular a c c o u n t
of financial gain. A m a t e u r s , like professionals, tend to specialize.
of the trilobites of New York.
S u m p t u o u s l y illustrated with
In New York, as in O n t a r i o , O h i o , I n d i a n a , O k l a h o m a , and
generous photographs of c o m p l e t e s p e c i m e n s of New York trilo-
U t a h — r e g i o n s that have a lot of fossiliferous Lower Paleozoic
bites, this b o o k is m o r e than a regional field guide. It also testi-
o u t c r o p — m a n y a m a t e u r s and fossil collectors c o n c e n t r a t e their
fies to G e r r y Kloc's expertise in preparation and Carlton Brett's
efforts on trilobites. T h e y have collected and prepared trilobite
keen insight about the rocks and c o m p l e x facies of the state. In
s p e c i m e n s that, in quality and c o m p l e t e n e s s , rival those described
essence, the b o o k reprises the w o r k of Charles Walcott, a n -
by a c a d e m i c paleontologists. T h e extent of p o p u l a r interest in
other accomplished a m a t e u r paleontologist of a c e n t u r y and a
trilobites is exemplified by h u n d r e d s of websites on the Internet,
quarter ago.
almost all of t h e m hosted by a m a t e u r s .
T h e technical literature on trilobites is vast. It is dispersed
T h e p h o t o g r a p h s in this publication reveal why trilobites have
through n u m e r o u s paleontological j o u r n a l s , in specialized b o o k s ,
long been considered to be a m o n g the m o s t desirable and curious
and as century-old m o n o g r a p h s . Even a dedicated trilobite pale-
of fossils. A late Paleolithic h u n t e r in w h a t - i s - n o w central France
ontologist with access to a university library would have difficulty
carried o n e a r o u n d his neck as a p e n d a n t suspended from a
retrieving all of it. T h e popular literature on trilobites is a lot
leather t h o n g . A n c i e n t C h i n e s e philosophers called t h e m " s t o n e
easier to access, if only because there is so little of it. Few profes-
s i l k w o r m s " and " b a t s t o n e s . " T h e Pahvant Ute tribe of western
sional paleontologists have considered it i m p o r t a n t to write field
Utah knew t h e m as timpe khanitza pachavee, m e a n i n g "little water
guides to fossils along the lines of the popular regional guides to
bug like stone house." Strung as amulets, they were thought
flowers, m u s h r o o m s , trees, insects, and birds that are available in
to possess magical powers. In 1 6 9 8 , Edward Lhwyd, c u r a t o r of the
every bookstore across A m e r i c a . Fewer still have written b o o k s
A s h m o l e a n M u s e u m in O x f o r d , included in the pages of the
exploring the natural history of fossils.
Philosophical
Trilobites of New York is a lavishly illustrated bestiary of New
Transactions of the Royal Society a
plate with
a
finely
lined oval fossil f r o m the shales exposed near Llandeilo in south-
York trilobites in which o n e can sense the spirit of S a m u e l Latham
ern Wales. He t h o u g h t it was a "flat fish." In nearby areas in Wales
Mitchill's m o n o g r a p h , The Fishes of New York, published in 1 8 1 5 .
suffused with the legend of King Arthur, such fossils are called
Both books are basically encyclopedic and scientific in their
" s t o n e butterflies" and are widely believed to have been e n t o m b e d
approach, but each includes snippets of practical i n f o r m a t i o n .
in rock by spells cast by the wizard Merlin.
Mitchill advised fishermen that the blackfish will run in the spr-
European naturalists were fascinated by these fossils. Although
ing when the dogwood b l o s s o m s o p e n . W h i t e l e y suggests that a
they described and figured t h e m in considerable detail, they
3 5 - m m T I F F c o l o r image of a trilobite is a b o u t 25 megabytes
had great difficulty in d e t e r m i n i n g what they were and how they
in size and should be stored on a C D - R O M . T i m e s c h a n g e !
should be
Here is a s u m m a t i o n of nearly two centuries of discovery and
applied
classified.
the
term
The
great
Entomolithus
naturalist paradoxus
Carolus
Linnaeus
("paradoxical
stone
study of New York trilobites by a succession of paleontologists
i n s e c t " ) to such fossils f r o m Sweden; others t h o u g h t they were
and as an exposition of the natural history of these fascinating
fossil crabs or possibly weird mollusks.
fossils. T h e b o o k will be w e l c o m e d especially by A m e r i c a n pale-
W i t h their evocative and disparate n a m e s , these stony objects
ontologists, professional as well as amateur, and by anyone who
were corralled in
delights in the exquisite beauty of these ancient fossils.
Ernst
Professional paleontologists working on New York fossils have
Immanuel
Naturgeschichte
der
1771 Walch
w h e n the G e r m a n naturalist lohann published
Versteinerungen
the
third
[Natural
volume
History
of Der
of Petrifac-
always been greatly o u t n u m b e r e d by a m a t e u r paleontologists and
tions]. In it he proposed a collective n a m e derived f r o m the most
avocational fossil collectors. Although often ( a n d mistakenly) dis-
obvious f e a t u r e — t h e i r t h r e e - l o b e d appearance. Eventually natu-
missed as dilettantes, amateurs ( t h e root is the Latin amator, for
ralists studying fossils ( w h o were now b e g i n n i n g to be called pale-
XI
FOREWORD
XII
ontologists) accepted that trilobites c o m p r i s e a distinct group of
support from the state legislature to prepare a single volume on
fossil a r t h r o p o d s .
the fossils of the state. Hall had greater a m b i t i o n s , and entirely
By the early years of the n i n e t e e n t h century, trilobites of m a n y
due to his s t u b b o r n d e t e r m i n a t i o n and ability to browbeat legis-
different types had been d o c u m e n t e d f r o m Britain, G e r m a n y ,
lators, this v o l u m e b e c a m e the first of no fewer than 13 quarto
Scandinavia, and B o h e m i a . T h e n , as now, they attracted attention
volumes of the m o n o g r a p h series Palaeontology of New York. T h e
because of their peculiar shape, their striking o r n a m e n t a t i o n ,
series c o m p r i s e d thousands of pages and m a n y hundreds of plates
and their great age. A m o n g the m o s t ancient of fossils, they were
published over the next half century. To pursue his work, Hall
f o u n d mainly in the sectors of Earth history s o o n to be n a m e d
amassed
the C a m b r i a n and Silurian systems.
Beaverkill in Albany. Of Hall it can truly be said that he never met
huge fossil
collections at his laboratory along the
Trilobites are the most lifelike of f o s s i l s — m a n y well-preserved
a fossil he didn't covet. He hired a succession of assistants to
specimens belie their great antiquity and seem almost ready
collect, prepare, describe, and draw the specimens. Hall h i m s e l f
to arch their bodies, peer a b o u t with their c o m p o u n d eyes, and
described m a n y trilobites from the state in his Palaeontology, but
crawl forward as if to c o n t i n u e a j o u r n e y that was interrupted
independently o n e of his assistants m a d e the class Trilobita
hundreds of millions of years ago. A trilobite is an ancient a r t h r o -
his o w n .
pod, but it is certainly not a lesser a r t h r o p o d .
Charles Doolittle Walcott was a young m a n of 26 when he
Trilobite discoveries in the New W o r l d followed closely on
started to work for Hall in 1876. B o r n at New York Mills in the
those in the Old. By 1832 so m a n y different kinds of trilobites
M o h a w k Valley, he had little formal education but a wealth of
had been collected that J a c o b G r e e n , a professor at Jefferson
practical knowledge about fossils. A few years previously he had
Medical College in Philadelphia, had sufficient material to write
sold a collection of trilobites he had compiled from Trenton Falls
a 9 3 - p a g e m o n o g r a p h detailing all the species then k n o w n . He
on West C a n a d a Creek to the M u s e u m of Comparative Z o o l o g y
might have titled it Trilobites of New York instead of A Monograph
at Harvard University for $ 5 0 0 0 . At night, after he had finished
of the
his w o r k for Professor Hall, Walcott polished sections of tightly
Trilobites of North America,
because
of the
32
species
he
dealt with, all but 7 c a m e f r o m that state.
enrolled s p e c i m e n s of the trilobite Ceraurus in an a t t e m p t to
New York was h o m e to the first A m e r i c a n s c h o o l of geology.
d e t e r m i n e the structure of its infolded limbs. This was e n o r -
1824 Stephen Van Rensselaer provided the funding that
m o u s l y difficult—akin to attempting the restoration of an orchid
allowed A m o s Eaton to start the Rensselaer S c h o o l in the town of
by slicing serially through a rolled-up f l o w e r — a n d , not sur-
In
Troy. T h i s school left a solid m a r k on early A m e r i c a n geology
prisingly, resulted in inaccurately reconstructed trilobite limbs.
and
of
Walcott also collected f r o m localities in New York where few trilo-
g e o l o g i s t s — o n e that effectively d o m i n a t e d A m e r i c a n geological
bites had been k n o w n b e f o r e . He m a d e large collections f r o m
paleontology.
It graduated
a
remarkable contingent
surveys—along with a few paleontologists who ensured that New
deformed
York remained the paleontological heartland of North A m e r i c a
and f r o m Upper C a m b r i a n limestones near Saratoga Springs.
for the rest of the nineteenth century. O n e of the Rensselaer
However, Walcott chafed at the treatment he received f r o m the
graduates was sure that he had f o u n d a living trilobite.
mercurial Hall, w h o after a few years dumped him for a younger
As a m e m b e r of the United States " E x p l o r i n g Expedition
Lower C a m b r i a n
rocks of the Taconic M o u n t a i n s
and m o r e c o m p l i a n t assistant. Walcott benefited by gaining a
o f 1830," James Eights o f Albany was the f i r s t A m e r i c a n scien-
position
tist to study the m a r i n e animals, l a n d f o r m s , and geology of
b e c a m e director of the survey, and rose to b e c o m e the secretary
in
the newly f o r m e d
U.S. Geological Survey, t h e n
Antarctica and its surrounding islands. A m o n g his discoveries
of the S m i t h s o n i a n Institution. Walch might have n a m e d it, b u t
from the shallow seas a r o u n d the bleak S o u t h Shetland Islands
it was Walcott w h o conceived the trilobite taxon. He was the first
was a peculiar creature that he n a m e d Brongniartia
trilobitoides
to suggest that the class Trilobita (or, as s o m e paleontologists now
Brongniartia
favor, phylum Trilobita) was a group of arthropods quite distinct
had
f r o m crustaceans.
and boltoni.
illustrated B.
alongside
boltoni was
a
its
large
presumed fossil
relative,
trilobite
that
been
described f r o m ancient Silurian shales scooped up by tarriers digging the Erie Canal near Rochester. And if B.
New York had to relinquish its primacy in matters trilobitic
boltoni was
in the early years of the twentieth century as the research focus
a stony extinct trilobite, then surely the lively trilobitoides m u s t
shifted to o t h e r parts of the c o n t i n e n t — t o the Great Basin of
b e living m e m b e r s o f that a n c i e n t clan. T h e Antarctic a n i m a l ,
Nevada and Utah, to N e w f o u n d l a n d , to Virginia, to the Upper
however, t u r n e d o u t to be a c r u s t a c e a n — a n isopod of the genus
Mississippi Valley, and to the southern C a n a d i a n Rockies. In the
Serolis.
But even today Serolis trilobitoides (Eights)
is cited as a
1960s a new crop of paleontologists applying m o d e r n paleonto-
t e x t b o o k e x a m p l e o f the convergent evolution o f isopods and
logical ideas sparked renewed interest in the New York trilobites
trilobites.
that had been described a century earlier. A m o n g these scientists
New York p a l e o n t o l o g y entered a new state-sanctioned phase
were F r a n c o Rasetti, the paleontologist/nuclear physicist from
in the early 1840s w h e n James Hall, the state paleontologist and
J o h n s H o p k i n s University w h o focused on C a m b r i a n trilobites
the b e s t - k n o w n graduate of the
from the tortured rock of the Taconic region; Harry W h i t t i n g t o n ,
Rensselaer S c h o o l , received
FOREWORD
XIII
the Woodwardian professor of geology at C a m b r i d g e University,
ing us full circle as they update and e n h a n c e the story of the trilo-
who restored the a n a t o m y of pyritized
bites of New York, bringing new visions and fresh perspective to
Triarthrus f r o m Upper
Ordovician shales near R o m e ; and Niles Eldredge, the p a l e o n t o l -
these wonderful creatures.
ogist at the American M u s e u m of Natural History in New York City, whose work ensured the centrality of M i d d l e Devonian Phacops
(now Eldrcdgeops)
in
the
new
evolutionary
model
of
punctuated equilibria. So the authors of this b o o k are to be congratulated for bring-
ROLF
LUDVIGSEN,
Head
D e n m a n Institute for Research on Trilobites D e n m a n Island, British C o l u m b i a , C a n a d a
Preface
S c i e n t i s t s estimate that life on Earth may have begun as early as three billion years ago. life
was
confined
to
For m u c h of its history, however,
single-celled
bacteria.
Stromatolites,
New York State is and has long been a m a g n e t for trilobite hunters. Historically, New York was of central i m p o r t a n c e in the study of Paleozoic fossils, and New York's trilobites were
layered m o u n d s of sediment trapped by mats of blue-green
among
cyanobacteria, are the p r e d o m i n a n t fossils for nearly two billion
York strata are the source of m a n y s p e c i m e n s accepted worldwide
years
as the best of their kind. T h e s e fossil
of geologic
history.
Finally,
in
the
late
Precambrian
the
first
illustrated
fossils
in
North
America.
New
remains are actively
Ediacarian Period, about 5 7 0 million years ago, e n i g m a t i c soft-
sought, studied, and traded. W i t h its extensive shale deposits,
bodied forms of multicellular life first appeared as impressions in
New York is a particularly rich source of trilobites, m a n y of
sandstone.
which are shown for the first t i m e in this v o l u m e . M a n y out-
About 543 million years ago life m a d e a further p r o f o u n d
standing localities in New York State, from the majestic O r d o v i -
change in direction. A sudden burst of new o r g a n i s m s with hard
cian limestone bluffs of Trenton Falls to the Silurian beds in the
skeletons in the fossil record has b e e n called the " C a m b r i a n
great gorge of Niagara River to the D e v o n i a n shale cliffs of Lake
Explosion." T h e earliest fossil skeletons were simple tubes, p r o b -
Erie, c o n t i n u e to yield a b u n d a n t and spectacular trilobite fossils.
ably made by w o r m s ; shell material clearly m a d e by c o m p l e x
New York strata have also yielded m o r e trilobites with preserved
living creatures such as mollusks appeared a b o u t 5 4 0 million
appendages and o t h e r "soft p a r t s " than almost any other region
years ago. T h e n , beginning about 5 2 0 million years ago, highly
o f the world. T h e rarity and aesthetic beauty o f c o m p l e t e o u t -
sophisticated
stretched or enrolled trilobites gives trilobite fossils special value
skeletons
of trilobites,
early
representatives
of
Earth's most a b u n d a n t c o m p l e x a n i m a l s — t h e Phylum A r t h r o -
to
p o d a — a p p e a r e d in m a r i n e strata worldwide. T h e trilobites not
ranging f r o m a few millimeters to nearly a h a l f - m e t e r in length,
only appeared dramatically in the fossil record but for millions of
are featured in m u s e u m s all over the world; s o m e extraordinary
years they d o m i n a t e d it. Trilobites are the quintessential archaic m a r i n e animals. Few
collectors.
Spectacular,
ornate
trilobites
from
New York,
examples are prized by collectors and have been sold for t h o u sands of dollars.
if any other invertebrate fossils have attracted m o r e attention
Yet despite the f a m e of New York State's trilobites, no recent
from paleontologists and fossil collectors than these ancient
text has a t t e m p t e d to d o c u m e n t comprehensively these remark-
arthropods, distant relatives of today's crustaceans and insects.
able fossils. W i t h a little effort o n e can find trilobites in New
Paleontologists have learned a great deal about trilobites because
York State rocks ranging in age f r o m the t i m e of their earliest
they were ubiquitous in the oceans and seas of the early Paleo-
o c c u r r e n c e in the Early C a m b r i a n up to their last t i m e of
zoic Era and because they possessed readily preserved hard skele-
m a j o r a b u n d a n c e in the Devonian Period, a b o u t 3 7 0 million
tons. In the mid to late 1800s lithographed images of trilobites
years ago. T h u s , although New York strata do not d o c u m e n t the
became symbolic of the rapidly developing field of paleontology
entire evolutionary history of trilobites, the a b u n d a n t , high-
in New York State as well as in E n g l a n d , two hotbeds of early
quality material available in this area offers a rare o p p o r t u n i t y to
research by serious amateurs and professional scientists when
discover and study these intriguing representatives of early life
interest in the nascent field of geology was first b e g i n n i n g to
history.
burgeon. T h e beautifully preserved, segmented exoskeletons of
Trilobites of New York is
intended
to be a
nearly complete
trilobites—in shades of saddle brown and blue gray to b l a c k —
c o m p i l a t i o n of the trilobite species f o u n d in New York: a review
are truly spectacular o b j e c t s , but perhaps above all it is the well-
of the biology of the trilobite; insight into trilobite preservation
developed, c o m m o n l y c o m p o u n d eyes of trilobites that have
in the rocks; a s h o r t course on the Paleozoic geology of New York,
made them attractive to paleontologists and lay persons alike.
emphasizing trilobite-bearing strata; and a collection of high-
Trilobites were certainly a m o n g the first organisms to f o r m rela-
quality images of representative New York trilobites. T h e b o o k
tively clear images of their world.
is not and was never intended to be a field guide or identificaxv
PREFACE
XVI
tion m a t r i x to trilobites. As s u c h , there is no specific local-
the basis of quality, rarity, and representation of the material
ity i n f o r m a t i o n , although
present in the New York rocks.
tographs very useful
in
m a n y readers will
find
identification and in
the p h o -
differentiating
similar species.
Anyone w h o collects fossils of any kind understands that finding a c h o i c e specimen is only part of the process. Most trilo-
T h i s work started m o r e than 20 years ago as an attempt by
bites are e m b e d d e d in a m a t r i x of shale or limestone, and to really
T o m Whiteley to c o m p i l e illustrations of the trilobites found in
appreciate their quality o n e must prepare t h e m by removing the
New York. Although New York has a history of trilobite discov-
stone f r o m the part of the trilobite that is to be displayed. Most
ery and research since 1824, references on trilobites are scattered
of the illustrated s p e c i m e n s were prepared or " t o u c h e d u p " by
and often not available except in the libraries of large universi-
Gerald Kloc. Even s o m e m u s e u m specimens were worked o n ,
ties. T h e only collective works on New York trilobites were the
with the m u s e u m ' s permission, to bring out the details concealed
classic volumes by James Hall, and the last of these was published
by m a t r i x .
in 1888. It soon b e c a m e apparent that the New York Paleozoic
As work on this project progressed, it b e c a m e clear that to
exposures are too varied for o n e person to really understand all
c o m p i l e data and images on trilobites was not e n o u g h . A listing
the trilobites and their l o c a t i o n s . H e n c e , Gerald K l o c b e c a m e
of nearly 5 0 0 separate species, while interesting to a few special-
involved with this project for his knowledge of the Silurian and
ists, is not very helpful to the collector or the student. To be really
Devonian exposures and their trilobites and for his contacts in
useful, we needed to include i n f o r m a t i o n on why the trilobites
the amateur c o m m u n i t y .
are f o u n d where they are and how their preservation c o m e s
As in all research p r o g r a m s , b a c k g r o u n d literature is an essen-
a b o u t . To this e n d , Carlton Brett provided a review of trilobite
tial starting point. T h e r e are a few texts on trilobites that provide
t a p h o n o m y , as well as an overview of the geological history of the
m o r e in-depth i n f o r m a t i o n on the a n i m a l itself than we include.
New York Paleozoic.
T h e works
of Johnson
(1985),
Levi-Setti
(1975),
Ludvigsen
T h e r e m a i n i n g issue c o n c e r n e d the intended audience, or who
( 1 9 7 9 b ) , and W h i t t i n g t o n ( 1 9 9 2 ) are g o o d references for addi-
is expected to read the b o o k . Dr. Warren Allmon of the Paleon-
tional reading. Every trilobite publication has references, and
tological Research Institution suggested that high-school earth
these references lead to o t h e r p u b l i c a t i o n s , which in turn lead to
science teachers represented the right level for content, as this
m o r e references and s o o n . H u n d r e d s o f publications were e x a m -
level would provide i n f o r m a t i o n useful to the collector, teacher,
ined, and the relevant o n e s were put into a database. Fieldwork
and student. Dr. Allmon also made the first contacts with Cornell
was also carried out in the m o r e p r o m i s i n g exposures. However,
University Press.
this fieldwork resulting f r o m literature surveys was limited and
As already m e n t i o n e d , it was necessary in the course of this
nowhere near the h o u r s and days of work spent by m a n y p r o -
work to visit m a n y of the m a j o r natural history m u s e u m s in
fessionals and amateurs in the field collecting each individual
the northeast United States. T h e A m e r i c a n M u s e u m o f Natural
specimen. S p e c i m e n s of the quality illustrated in this b o o k are
History, M u s e u m o f C o m p a r a t i v e Z o o l o g y (Harvard), Peabody
u n c o m m o n , even rare. A n u m b e r of the trilobite s p e c i m e n s are
M u s e u m (Yale), New York State M u s e u m , National M u s e u m of
unique in their quality of preservation and preparation, and very
Natural History ( S m i t h s o n i a n ) , Rochester M u s e u m and Science
few like them exist anywhere.
Center, Royal O n t a r i o M u s e u m , and Paleontological Research
T h e trilobite collections in a n u m b e r of m a j o r n o r t h e a s t e r n
Institution were visited, s o m e m a n y times, and their collections
United States m u s e u m s were e x a m i n e d carefully, and s p e c i m e n s
carefully e x a m i n e d . T h e c o o p e r a t i o n o f the m u s e u m s ' m a n a g e -
that were unusual or of high quality were p h o t o g r a p h e d and the
m e n t and their collections managers in particular was unreserved.
a c c o m p a n y i n g i n f o r m a t i o n recorded. T h e s e m u s e u m collections
W i t h o u t their help, this work would not have been possible.
represent the efforts of dozens of individuals over a period of
The
cooperation
and
assistance
of
Fred
Collier,
Jan
m o r e than 150 years. A n u m b e r of a m a t e u r collectors m a d e their
T h o m p s o n , Ed Landing, Niles Eldredge, Janet Waddington, T i m
s p e c i m e n s available for photography, which was helpful as the
W h i t e , Wendy Taylor,
best and most c o m p l e t e material is often n o t in a m u s e u m . In
Westrop, and G e o r g e M c i n t o s h were all i m p o r t a n t to this work.
Paul
Krohn,
Fredrick
Shaw,
Stephan
a few cases research paleontologists m a d e their p h o t o g r a p h s of
Fred Collier, in particular, while at the United States National
uncommon
M u s e u m , greatly influenced the early direction of these efforts
material available
for
reproduction.
The
photo-
graphic procedures are provided in A p p e n d i x B, b u t in general
with his professionalism and enthusiasm.
the p h o t o g r a p h s were taken in a m u s e u m or in a l a b o r a t o r y envi-
We gratefully acknowledge the collectors w h o m a d e their
r o n m e n t . O f t e n the s p e c i m e n s were whitened with a m m o n i u m
s p e c i m e n s available for p h o t o g r a p h y and in s o m e instances
c h l o r i d e to b r i n g o u t detail. T h e images were then scanned into
donated these s p e c i m e n s to a m u s e u m . T h e y are William P i n c h ,
a digital file, and all of the final preparation of images was d o n e
Kent S m i t h , Lee Tutt, Paul K r o h n , James Scatterday, Gregory
on c o m p u t e r . No i n f o r m a t i o n was added or subtracted from the
Jennings, Fred Barber, Kym Pocius, S a m Insalaco, Kevin Brett,
digital image at any t i m e . Of the thousands of p h o t o g r a p h s , o n l y
Steve Pavelsky, Tod C l e m e n t s , Douglas DeRosear, Fred Wessman,
a b o u t 2 0 0 could be selected for the b o o k . Selection was m a d e on
G o r d o n Baird, and William Kirchgasser.
PREFACE
xvii
Rolf Ludvigsen, Nigel Hughes, and G e o r g e M c i n t o s h read early drafts of the b o o k and m a d e m a n y valuable suggestions. Warren Allmon made the first contacts with
Sandoval, Lou R o b i n s o n , and C a n d a c e Akins also provided valuable assistance. To all we express o u r gratitude.
Peter Prescott,
science editor of Cornell University Press, w h o was i n s t r u m e n t a l
T h o m a s E. Whiteley
in giving the b o o k focus and helped turn what was a collection
Gerald J. Kloc
of information and pictures into s o m e t h i n g publishable. Alyssa
Carlton E. Brett
T Trilobites of New York
1
Background Information
Historical Notes
Lyceum of Natural History of New York was established in New York City, and in 1823 the Albany Lyceum of Natural History
E. Lhwyd provided the first record of trilobites in the litera-
was f o u n d e d .
Isotelus gigas was described
of Natural History (New Y o r k ) .
in
the Journal of the
ture in 1 6 9 8 , with the publication of plates depicting two Welch
Lyceum
trilobites, identified as fish. In 1 7 7 1 , J. I. Walch originated the
the Trenton L i m e s t o n e of central New York, particularly Trenton
T h e Isotelus fossils
from
use of the n a m e " t r i l o b i t e " as a distinct class of a n i m a l . L. D.
Falls, were long k n o w n and collected for sale by the local residents
H e r r m a n n , however, used the term trilobus as part of the n a m e
and b e c a m e part o f m a n y early natural history collections. T h e
for a trilobite fossil, as early as 1 7 1 1 . ( F o r the very early trilobite
Arctinurus s p e c i m e n described by Bigsby was first f o u n d during
references, see the publications by H. B u r m e i s t e r ( 1 8 4 3 , 1 8 4 6 ) . ) In 1822, C. Stokes was the first to describe North A m e r i c a n
the digging of the Erie Canal locks in what is n o w L o c k p o r t , New York.
from
In 1 8 3 6 , New York began a general natural history survey of
Canada. J. E. DeKay provided the first unequivocal description
the state, including its geology and mineralogy, and at the same
of a New York trilobite, Isotelus gigas from Trenton Falls ( n o r t h
t i m e f o r m e d the New York Geological Survey. T h a t same year the
trilobites,
with
Asaphus
(now
Isotelus)
platycephalus
of Utica, New York), in 1824. T h i s report was followed by that of
first state paleontologist was n a m e d , T. A. C o n r a d , a Philadelphia
Arctinurus
conchologist.
boltoni
by
Bigsby
in
1825.
Qf
the
40
trilobites
described in the classic works by the Philadelphia physician J. Green in 1832 and 1835, most were from New York. New York State
took an
early leadership
role
For the geological survey the state was divided into four districts, and the results from each district were published as sepa-
in
North
rate v o l u m e s . Starting in 1 8 4 2 , the first of these was published.
American Paleozoic invertebrate paleontology, in part due to
The
the n u m b e r of lower Paleozoic exposures within the state and also
b e g i n n i n g of the career of New York's s e c o n d and most well-
Geology of the Fourth
District of New
York
(1843)
was
the
to the history of the state itself. T h e early 1800s saw a general
k n o w n state paleontologist, James Hall. Hall was also the princi-
expansion westward within the United States. New York par-
pal a u t h o r of the e i g h t - v o l u m e Palaeontology of New York, issued
ticipated both by pressing settlement into the rich farmlands
between 1847 and 1 8 9 4 . V o l u m e s 1, 2, 3, and 7 (written with
of western New York and by aggressively seeking to b e c o m e the
J. M. Clarke) c o n t a i n significant trilobite i n f o r m a t i o n and are the
c o m m u n i c a t i o n route to the nation's Midwest. Roads, canals,
p r i m a r y references for early trilobite work in New York. Hall had
and permanent c o n s t r u c t i o n were all part of these goals, and
a n u m b e r of assistants w h o began their careers with h i m : F. B.
all needed building stone to succeed. L i m e s t o n e was the ideal
M e e k , F. V. Hayden (future director of the United States Geolog-
material both for buildings and for the c e m e n t and m o r t a r to
ical Survey), C. A. W h i t e (future state paleontologist for Iowa),
hold them together. T h u s , small and large limestone quarries
W. A. G a b b , R. P. Whitfield, C. Calloway, C. D. Walcott (future
became c o m m o n along the H u d s o n - M o h a w k River corridor.
director of the United States Geological Survey and the secretary
T h e state government also was c o n c e r n e d about its knowledge
of the S m i t h s o n i a n I n s t i t u t i o n ) , C. E. Beecher (future professor
of the natural treasures c o n t a i n e d within its b o r d e r s . In 1818 the
at Yale University), and J. M. Clarke (future state paleontologist 1
BACKGROUND
INFORMATION
for New York). Hall was a difficult m a n to work with and c o n s e -
usually derived
quently had a high turnover in assistants. It is claimed that Hall
Greek, or I n d o - E u r o p e a n and are selected by the describing
t o o k on s o m e of his assistants to gain access to their personal
author. N a m e s are often latinized, and the gender of the species
fossil collections (Yochelson, 1 9 8 7 ) .
follows that of the genus. In other words, if the genus n a m e is
T h e turn o f the c e n t u r y introduced additional
important
c o n t r i b u t o r s to the knowledge of New York trilobites, such as R. R u e d e m a n n and P. R a y m o n d . By the early twentieth century,
from
Latin, ancient Greek, latinized ancient
c h a n g e d , the ending on the species n a m e must s o m e t i m e s change to agree with it in gender. G e n e r a , that are considered to be closely related on the basis
New York was no longer a m a j o r area for new trilobite discover-
of shared characteristics, are grouped into families.
ies, as the focus had shifted westward with the general expansion
families are larger and m o r e distinctive, it is often easier to deter-
of the United States. However, significant c o n t r i b u t i o n s are still
m i n e the family to which a new trilobite belongs than to deter-
m a d e today, for example, in the u n d e r s t a n d i n g of s o m e less well-
m i n e its genus. New genera are constantly being erected, and
described areas such as the Middle O r d o v i c i a n Chazy G r o u p and
trilobite species are frequently moved a r o u n d as descriptive
the C a m b r i a n in eastern New York. T h e general shift in e m p h a -
m e t h o d o l o g y b e c o m e s m o r e sophisticated and new classification
sis f r o m discovery to understanding still keeps New York trilo-
standards are adopted.
Because
bites in the limelight. In later chapters we will point out the
Families are further collected into orders, again based on
i m p o r t a n c e of New York trilobite beds in o u r understanding of
inferred evolutionary relationships. T h e r e are currently eight
trilobite biology and fossil preservation.
orders in the class Trilobita of the phylum Arthropoda (Kaesler, 1 9 9 7 ) . T h e r e are additional t a x o n o m i c relationships rarely used herein, such as superfamily and suborder. Family n a m e s always
Trilobite Names
have the suffix -idae; superfamily names, -acae; suborder, -ina;
Trilobites are n a m e d using the rules of zoological n o m e n c l a ture published in English and French in the International Code of Zoological Nomenclature ( I C Z N ) . T h i s c o d e is used worldwide by
and order, - i d a . * The common
New York trilobite
Eldredgeops rana
is taxo-
nomically described as follows:
all scientists irrespective of the language of p u b l i c a t i o n . In dealing with the names of trilobites ( o r any o t h e r kind of o r g a n i s m ) , it
phylum
helps to understand the basic rules, how n a m e s c o m e a b o u t , and
Arthropoda
how they can change over t i m e .
class
For example, and as m e n t i o n e d already, in 1824 J. E. Dekay first reported Isotelus gigas Dekay,
Trilobita
1 8 2 4 , a n a m e that remains
order
unchanged to this day. T h e first n a m e , with a capital first letter,
Phacopida
Isotelus, is the genus n a m e and refers to a group of a n i m a l s in
family
which similar characteristics indicate a close evolutionary rela-
Phacopidae
tionship. G e n u s names must be original and not used for any
genus
other grouping of fossil or living a n i m a l . T h e second mme, gigas,
Eldredgeops
which is not capitalized, is the species n a m e and ideally should
species
refer only to a coherent group of interbreeding populations.
rana
Species n a m e s do not have to be u n i q u e , except within the s a m e genus. T h e r e can be only o n e gigas within the genus Isotelus, but
To take a n o t h e r , s o m e w h a t m o r e c o m p l e x example, Eldred-
species n a m e s can and do reoccur in different genera (plural of
geops
genus). Accordingly there are seven different New York trilobite
(short for variety) rana by J. Green in 1832. (Green in the s a m e
genera with the species n a m e trentonensis.
T h e proper n a m e ,
rana
publication
(Green, had
1832)
described
was
first
named
Calymcne bufo
Calymene bufo from a
var.
poorly pre-
genus and species, is italicized in print. In descriptive literature
served phacopid s p e c i m e n in a float boulder. T h e c o n d i t i o n of
the n a m e of the describing author (Dekay in our e x a m p l e ) and
the fossil was too p o o r to use for determining clear relationships
s o m e t i m e s the date of publication ( 1 8 2 4 in o u r e x a m p l e ) follow
and the n a m e subsequently was a b a n d o n e d . ) In 1860 E m m o n s
the n a m e . C h a n g e s to the genus n a m e are not u n c o m m o n , and
changed the species to Phacops bufo because of the greater simi-
in these cases the n a m e of original a u t h o r and date are given in
larity of the genus to the European genus Phacops than to Caly-
parentheses.
mene.
T h e e t y m o l o g y of trilobite n a m e s often refers to a m o r p h o logical
feature.
Hall ( 1 8 6 1 ) first called the c o m m o n trilobite from the
Hamilton
shales
and
limestones,
Phacops rana.
Green's
name
Isotelus m e a n s " s i m i l a r " (iso-) " e n d " or " t a i l "
and publication date now appear in parentheses because of the
(-telus), referring to the similarity between the head and tail of
c h a n g e in his original genus designation. T h i s story is further
this species, a n d gigas m e a n s " l a r g e " or "giant," referring to the
complicated by the assignment of s o m e new phacopids to s u b -
large size of this species c o m p a r e d to most trilobites. N a m e s are
species of Phacops rana such as Phacops rana milleri Stewart,
1927
TRILOBITE
3
NAMES
and Phacops rana rana ( G r e e n , 1 8 3 2 ) . ( T h e designation of s u b -
representative, then this specimen b e c o m e s a lectotype. Other
species is not often used with trilobites because strictly speaking
s p e c i m e n s in the original series b e c o m e p a r a l e c t o t y p e s , and the
the term implies geographically separated populations that could
t e r m syntype can no longer be applied. If the species has no orig-
interbreed given the opportunity. T h i s is nearly impossible to
inal type s p e c i m e n s that can be f o u n d and a sufficient taxonomic
determine from fossils, and most authors prefer the single species
purpose is present, an a u t h o r may designate a specimen to rep-
names Mich as Phacops rami ami Phacops milleri.) Struve ( 1990)
resent the type for the species. T h i s specimen is called a neotype.
re-examined the New World "Phacops" species and f o u n d t h e m
If at all possible, the n e o t y p e should be from the same location
significantly different from the type species Phacops latifrons that
and horizon as the originally described material. T h e description
was originally described from the Devonian of Germany. ( T h e
and n a m e m u s t be publicly issued as a p e r m a n e n t scientific
type species is the single species used to describe and define the
record and available in multiple, identical copies. All these rules
genus.)
are t h o r o u g h l y spelled o u t in the I C Z N ( 1 9 8 5 ) .
He erected
a
new genus, Eldredgeops, with
Eldredgeops
milleri as the type species. T h e very familiar f o r m e r Phacops rana is thus now properly referred to as Eldredgeops rana.
O t h e r type designations are c o m m o n l y used in collections but do not bear I C Z N r e c o m m e n d a t i o n . H y p o t y p e is a specimen that
Species n a m e s are never changed by later a u t h o r s , not even to
was referred to, usually in publications, to extend or correct the
correct spelling errors. T h e exceptions to this are if the n a m e has
knowledge of a species. T o p o t y p e refers to a specimen from
already been used for a closely related animal in the s a m e genus
the type locality, and p l e s i o t y p e refers to s p e c i m e n s very close to
or if the same animal has been n a m e d by a n o t h e r person in an
the type. P l a s t o t y p e is an artificial cast of the original type.
earlier publication. In almost all cases, priority is with the n a m e given by the first author.
A difficulty o n e often e n c o u n t e r s with trilobites, as well as o t h e r fossils, is that species were originally n a m e d when only a
T h e n u m b e r of trilobite species and genera is constantly
partial s p e c i m e n was available. T h e r e are a n u m b e r of instances
increasing due to b o t h new finds and redescriptions of previously
where, for e x a m p l e , the pygidium of an u n c o m m o n trilobite bore
collected material. T h e r e are also differing a p p r o a c h e s to the
o n e n a m e and the c e p h a l o n a different o n e . Also in the 1800s
concept of species. S o m e authors view speciation on the basis of
trilobites were often identified with the s a m e n a m e s as species
small external changes and tend to propose new species based on
f r o m o t h e r locations but of the same geological age. A n u m b e r of
these differences. O t h e r s view m a n y small external differences
New York trilobites, for e x a m p l e , were given the s a m e names as
as
species from the Midwest, particularly O h i o , as well as s o m e from
within
the
normal
intraspecies
variation
and
include
a
wider variety of s p e c i m e n s within a single species. T h e concept
Europe. S o m e o f these n a m e s are o n l y n o w being corrected a s
of species is not u n a m b i g u o u s in extant animals, and in the case
careful studies are m a d e .
of fossils morphological features are usually all there is available
A n o t h e r interesting situation is that early in the twentieth
for evaluation. Statistical evaluation of fossils using m e a s u r e -
century, scientists going through m u s e u m collections saw differ-
ments of key features is often currently used to define intraspecies
ences in s p e c i m e n s and gave t h e m new n a m e s , or listed t h e m as
variability, and the c o m p a r i s o n of derived (uniquely shared)
subspecies, by n o t i n g the n a m e on a label and leaving it with the
characteristics between closely related species is used to deter-
s p e c i m e n . T h e s e " m u s e u m l a b e l " n a m e s are c o m m o n l y e n c o u n -
mine their evolutionary relationship. S y s t e m a t i c s is the study of
tered with the Ordovician trilobites at the National M u s e u m of
the similarities and differences in o r g a n i s m s and their related
Natural History ( S m i t h s o n i a n o r U S N M ) . M u s e u m label names
species. A. B. S m i t h ( 1 9 9 4 ) presented an excellent in-depth review
are not recognized by the I C Z N and have no priority or recogni-
of systematics for the fossil record.
tion, except when subsequent a u t h o r s c h o o s e to use t h e m to
T h e rules of zoological n o m e n c l a t u r e now require that an
name specimens.
Later a u t h o r s
recognized
these
unpublished
men that clearly exemplifies this new species. T h i s specimen
s c r i p t " ) . T h e official date for the n a m e is when it is published,
should then be deposited in an appropriate public collection,
however, not when the m u s e u m label was m a d e . An example of
such as a m u s e u m . T h i s o n e specimen is called the h o l o t y p e .
such a n a m e is Isotelus walcotti Ulrich in C. D. Walcott, 1918. In
Other specimens of a
reference g r o u p
this case E. O. Ulrich saw differences between the specimens from
hypodigm)
the
(the " t y p e series" or
n a m e s with
sometimes
author, when describing a new species, must designate a speci-
the designation " M S " (for " m a n u -
called
the New York Trenton L i m e s t o n e , which were being called Isotelus
paratypes. In the 1800s and early 1900s authors often illustrated
iowensis, and the a u t h e n t i c trilobite f r o m Iowa. He n a m e d the
their new specimens but failed to designate a single type speci-
New York species /. walcotti on a m u s e u m label, and C. D. Walcott
men and its repository. Later authors in referring to these speci-
recognized the n a m e in a subsequent publication in 1918. T h e r e
mens, provided they could be f o u n d , consider the m e m b e r s of the
is no specific rule or protocol for the recognition of m u s e u m label
from
which
holotype
was
chosen
are
type series to be syntypes. T h e term c o t y p e is also seen in c o l -
n a m e s , and it is solely to the discretion of the publishing author
lections; it is a synonym for syntype or paratype and its use is dis-
whether the n a m e is recognized or not. Walcott chose to recog-
couraged by the I C Z N . Should an a u t h o r need to c h o o s e a single
nize Ulrich; thus it is appropriate, but not required, to add his
specimen from the designated syntypes to be the single species
n a m e to the final f o r m a l trilobite n a m e .
The Biology of Trilobites
T r i l o b i t e s are the earliest u n a m b i g u o u s arthropods found in the
Exoskeleton
fossil record, evidently because they were the first a r t h r o p o d s to develop the mineralized skeleton necessary for frequent preser-
T h e word trilobite, freely translated from Latin, m e a n s " h a v i n g
vation. M o d e r n arthropods have o r g a n i c e x o s k e l e t o n s that are
the nature of three lobes." T h e n a m e refers to the three length-
often strengthened with minerals such as calcite. In contrast,
wise, lateral parts or lobes of the trilobite body (Figure 2.1 A ) , not
trilobites had an exoskeleton c o m p o s e d primarily of calcite,
the three parts m a k i n g up the b o d y — t h e cephalon or head
although it undoubtedly was modified with organic materials or
(Figure 2.1 D ) , t h o r a x (Figure 2 . 1 E ) , and pygidium or tail (Figure
other minerals. T h e appendages, legs, and a n t e n n a e were p r o b a -
2 . I F ) . T h e central of the three lobes is referred to as the axial lobe
bly an organic material like the chitin of extant a r t h r o p o d s , which
(Figure 2 . I B ) and the side lobes of the thorax and pygidium, as
is o n l y preserved when replaced by minerals under special c o n -
the pleural lobes (Figure 2 . 2 C ) .
ditions (see C h a p t e r 3 ) . N o n e of the organic skeletal materials
Trilobites
and
other
arthropods
probably
evolved
from
have survived directly in the fossil record. T h e word a r t h r o p o d
annelid wormlike ancestors. T h i s is reflected in their segmented
m e a n s " j o i n t e d foot or leg," and the phylum A r t h r o p o d a includes
b o d y and the observation that each segment, whether fused
trilobites, crabs, lobsters, spiders, horseshoe crabs, centipedes,
together or j o i n t e d , carries a pair of appendages. T h e segments in
millipedes, and the largest of all living a n i m a l groups, the insects.
the front of the b o d y are fused to form the cephalon, and those
T h i s large group includes animals with strong external skeletons
in the rear of the b o d y are fused to f o r m the pygidium. T h e
that must be shed periodically to enable physical growth. M a n y
central segments f o r m i n g the thorax or trunk were j o i n e d by flex-
also go through o n t o g e n e t i c phases in their growth, which can
ible tissue that enabled m a n y trilobites to flex inward to the point
include free-ranging n e a r - m i c r o s c o p i c larvae.
of enrolling (Plate 1 0 9 ) , but probably did not allow for m u c h , if
T h i s chapter is divided into four parts: the external skeleton
any, sideway flexing. S o m e trilobites are found arched or flexed
or exoskeleton, the growth phases or ontogeny, the appendages
dorsally, which
and internal a n a t o m y ( t h e unmineralized or soft b o d y p a r t s ) , and
culation. For a m o r e detailed a c c o u n t of the elements of trilo-
indicates the flexibility of the trilobite arti-
the m o d e of life of trilobites. T h i s order roughly c o r r e s p o n d s to
bite articulation, see the publications by Whittington ( 1 9 9 2 ) ,
the level of knowledge about the biology of trilobites, as most is
B e r g s t r o m ( 1 9 7 3 ) , Levi-Setti ( 1 9 7 5 , 1 9 9 3 ) , M o o r e ( 1 9 5 9 ) , and
k n o w n a b o u t the exoskeleton and least is known about the life-
Kaesler ( 1 9 9 7 ) . T h e work by M o o r e ( 1 9 5 9 ) , Treatise on Inverte-
m o d e . T h e last part, l i f e - m o d e , is inferred from knowledge of
brate Paleontology, Part
trilobites in the fossil record and observations of living a r t h r o -
simply as the Treatise. Kaesler's publication ( 1 9 9 7 ) is the first of
O, A r t h r o p o d a
1, often
is referred
to
pods. All of the illustrations were c h o s e n from trilobite genera
a three-part revision in progress but only the first part has been
f o u n d in New York.
released. F o u r t e r m s are used repeatedly in describing trilobites. T h e s e are dorsal, m e a n i n g the uppermost surface of the body in the animal's life position; ventral, the lower surface of the body;
•1
FIGURE 2 . 1 . Trilobite structure using Eldredgeops rana (PRI 4 9 6 5 6 , w h i t e n e d ) . A. The three lobes from w h i c h the n a m e trilobite w a s d e r i v e d . B. The axial lobe. The axial lobe is s u b d i v i d e d into the thoracic axis a n d the p y g i d i a l axis. C. The pleural lobes. These may be further d e f i n e d as thoracic pleurae a n d p y g i d i a l pleurae. D. The c e p h a l o n or h e a d of the trilobite. E. The thorax. F. The p y g i d ium or tail. G. The glabella. H. The eyes. I. The p a l p e b r a l lobes on top of the eyes.
FIGURE
2 . 2 . Trilobite
structure
using
Ketlneraspis
tuberculata
(GJK
collection,
whitened).
A.
The
exoskeleton without the right free c h e e k . B. The genal spine e x t e n d i n g off the free cheek (arrow). C. Lateral thoracic pleural s p i n e s (arrows). D. Pygidial spines (arrow). E. Anterior c e p h a l i c s p i n e s (arrow). F. Axial n o d e s , raised areas on the thoracic axis (arrows). G. Axial o c c i p i t a l n o d e (arrow). H. Pustules, small, r a n d o m l y scattered raised areas (arrow).
7
EXOSKELETON a n t e r i o r , toward the front; and p o s t e r i o r , toward or at the rear of
T h e glabella is the dorsal covering of the s t o m a c h of the trilo-
the body part being described. Dorsal and ventral are absolute
bite. It usually has lateral grooves in its surface known as lateral
terms in the sense that the dorsal and ventral surfaces are the
glabellar f u r r o w s (Figure 2 . 3 G ) . T h e furrows rarely cross the
same regardless of the part being described or its o r i e n t a t i o n .
surface completely but can be deep, f o r m i n g p r o m i n e n t areas on
Anterior and posterior relate to the particular part or parts being
the glabella called lateral glabellar l o b e s (Figure 2 . 3 F ) or simply,
described. T h u s , a suture, or inflexible j o i n i n g , might be anterior
glabellar lobes. Because of the use of furrows and lobes in trilo-
to o n e body part and posterior to another.
bite identification, they are designated starting f r o m the occipital
T h e hard mineral exoskeleton, also called the c u t i c l e , is a
ring and occipital furrow. T h e furrow or sulcus separating the
complex structure. T h e external surface is variously o r n a m e n t e d
occipital ring f r o m the glabella is labeled S O ; the next most ante-
with ridges, terrace lines, n o d e s (Figure 2.2F, G ) , pustules (Figure
rior glabellar furrow is S I , a n d so o n . ( T h e O in SO and LO refers
2 . 2 H ) , tubercles, and spines (Figure 2 . 2 B , C, D ) . Terrace lines are
to " o c c i p i t a l " a n d is n o t a zero.) T h e lobes are similarly desig-
c o m m o n on the trilobite exoskeleton and are described in s o m e
nated, with the occipital ring called L O , the lobe directly anterior
detail by Miller ( 1 9 7 5 ) . Nodes are discrete, r o u n d e d , raised areas
to it L I , and so forth. It is not always easy to distinguish the most
on the dorsal exoskeleton, which are usually bilaterally s y m m e t -
anterior lateral lobes because the furrows can be very faint; thus,
rical (Plates 45 and 1 3 4 ) . Pustules, on the o t h e r h a n d , are raised
the most a n t e r i o r p o r t i o n of the glabella is called La, for anterior
areas that are m o r e frequent on the surface and also tend to be
glabellar lobe. T h e furrow separating the glabella from the cheek
more r a n d o m l y distributed (Plates 24 and 2 5 ) . Large pustules
area (Figure 2 . 3 H ) is the glabellar furrow. On m a n y trilobites the
are often called tubercles (Plate 2 7 ) . T h e r e c o m m o n l y are c h a n -
edge of the c e p h a l o n is distinctive (Figure 2.31) and is called the
nels from the surface of these structures to the interior, and it is
border.
believed
that
these
channels
served
for
sensory
capability,
T h e cheeks generally bear the eyes of the trilobite (Figure
enabling the trilobite to sense currents and chemical changes
2 . 1 H ) . ( T h e r e are eyeless, presumably b l i n d , trilobites but these
to the e n v i r o n m e n t (Figure 2 . 6 ) . S o m e of these perforations also
are an exception a n d will be n o t e d in the specific descriptions.)
may have been follicles for sensory hairs. Dorsal spines are the
T h e eye is often p r o m i n e n t l y raised, actually being on a stalk, in
physically extended equivalents to nodes (Plates 46 and 1 2 8 ) .
a few species. T h e area between the eye and the glabella is called
Spines, which extend or radiate from the edges of body parts, will
the palpebral area (Figure 2.11) and can have its o w n furrows and
be discussed later.
lobes.
T h e cephalon is the most c o m p l e x and the m o s t i m p o r t a n t
T h e surface of the eye has multiple lenses to form images,
part of the trilobite to be understood by the student or collector
a n d this surface can be very distinctive. Eyes with a closely
because it is often the m o s t easily recognized evidence for trilo-
packed optical structure a n d a s m o o t h , c o n t i n u o u s o u t e r surface
bites in the rocks.
The center of the cephalon is the glabella
( c o r n e a ) are called h o l o c h r o a l (Figure 2 . 4 A ) . Although they have
(Figure 2 . 1 G , 2 . 3 E ) , a raised p o r t i o n with characteristics often
a s m o o t h a p p e a r a n c e , these are c o m p o u n d eyes, similar to those
important to the recognition of trilobite species. Although the
in s o m e m o d e r n insects. Eyes with discrete individual lenses,
glabella is treated here as separate from the occipital ring (Figure
each with its o w n corneal surface, are called s c h i z o c h r o a l (Figure
2.3F, the lobe labeled L O ) , the t e r m i n o l o g y used in the Treatise,
2 . 4 B ) . In addition, the lenses in schizochroal eyes are separated
most trilobite workers today include the occipital ring as part of
by a thick interlensal sclera. T h e r e is a third type of eye, resem-
the glabella (this latter protocol is used in the Kaesler ( 1 9 9 7 ) . Lat-
bling the schizochroal eye, f o u n d in the family Pagetidae, called
erally outward from the glabella are the cheeks or genae (sin-
a b a t h o c h r o a l (Jell 1 9 7 5 ) . A b a t h o c h r o a l eyes lack the deep inter-
gular, gena). T h e s e areas usually have sutures (Figure 2.5) that
lensar scleral p r o j e c t i o n and the intrascleral m e m b r a n e of schizo-
separate t h e m into free cheeks (Figure 2 . 3 C ) and fixed cheeks
chroal eyes.
(Figure 2 . 3 D ) , called librigenae and fixigenae, respectively. T h e
Holochroal eyes arc found in the majority of trilobites, w h i l e
librigenae usually separate from the cephalic area on m o l t i n g , and
the schizochroal eyes are f o u n d only in the s u b o r d e r Phacopina,
the fixigenae remain p e r m a n e n t l y attached. T h e glabella, together
which arose in the O r d o v i c i a n and disappeared by the end of the
with the fixagenae, is called the c r a n i d i u m (Figure 2 . 3 B ) . M a n y
D e v o n i a n . P h a c o p i n s are well represented in New York, and this
trilobite species, particularly in the C a m b r i a n , are differentiated
type of eye structure is often observed. T h e n u m b e r of optical
on the basis of details in their cranidia. T h e posterior part of the glabella, the occipital ring, is a raised portion almost always separated from the main body of the
elements in schizochroal eyes is usually less, often far less, than that in h o l o c h r o a l eyes. In a series of elegant e x p e r i m e n t s , Towe
(1973)
demon-
glabella by a groove. S o m e occipital rings have a central p r o m i -
strated that the eyes in at least two trilobites were single crystal
nently raised area, n o d e , or spine that is very characteristic for
calcite oriented to give high-quality imaging. Towe mounted
particular genera or species. Spines are often overlooked because
the eye surface of Eldredgeops rana and an Isotelus species and
of the ease with which they are broken o f f and lost during the
demonstrated
process of removing the trilobite from the rock.
species) and each lens of a schizochroal eye (E. rana) gave an
that
each
facet
of a
holochroal
eye
(Isotelus
FIGURE 2.3. The structure of the trilobite c e p h a l o n
using
Calymene s p e c i e s (S.
Insalaco collection,
w h i t e n e d ) ( c e p h a l o n only). A. C e p h a l o n lacking the right free c h e e k . B. The c r a n i d i u m (arrow). C. Free c h e e k (arrow). D. Fixed c h e e k s (arrows). E. The g l a b e l l a (arrow). F. The glabella, with the glabellar lobes n u m b e r e d (arrows). G. The glabella, with the lateral glabellar furrows n u m b e r e d (arrows). H. The glabellar furrows (outlined, with arrows). I. The c e p h a l i c border (arrows).
9
EXOSKELETON
FIGURE
2.4.
Trilobite
eyes.
holochroal e y e s (arrow). B.
FIGURE 2.5.
A.
C e p h a l i c sutures. A.
c e p h a l i c sutures (arrows),
Monodechenella
macrocephala
(G.
Jennings
collection,
whitened)
with
Viaphacops bombifrons ( G J K c o l l e c t i o n , w h i t e n e d ) with s c h i z o c h r o a l eyes (arrow).
Ceraurus pleurexanthemus (GJK c o l l e c t i o n , w h i t e n e d ) s h o w i n g p r o p a r i a n
both e n d s e m e r g i n g anterior to the g e n a l a n g l e .
B.
Calymene niagarensis (S.
Insalaco collection) with g o n a t o p a r i a n c e p h a l i c sutures (arrows), the posterior e n d e m e r g i n g at the g e n a l angle. O n e free c h e e k has b e e n lost on the right side. C. Isotelus maximus (PRI 4 9 6 5 1 ) with o p i s t h o p a r i a n c e p h a l i c sutures (arrows), w h e r e the posterior e n d e m e r g e s a l o n g the rear of the c e p h a l o n . D. Calyptaulax callicephalus (GJK c o l l e c t i o n , w h i t e n e d ) , a trilobite in w h i c h the facial sutures are f u s e d a n d do not s e p a r a t e u p o n molting. This is c o m m o n in the order P h a c o p i d a .
inverted image when viewed from the rear, just as a simple glass
showed clear evidence of optical fibers extending f r o m the lens
lens does.
into the central c e p h a l o n . O n e asteropyge in their study also had
S t u n n e r and Bergstrom ( 1 9 7 3 ) studied the internal structure
similar fibers e x t e n d i n g f r o m the lens. T h e s e structures were c o n -
of the eyes of Phacops s p e c i m e n s f r o m the H u n s r i i c k slates in
sidered c o m p a r a b l e to similar structures in extant a r t h r o p o d s .
Germany. S o m e of the soft tissue of the trilobites was replaced by
Structures of this kind were reported previously in asteropyges
the mineral pyrite (i.e., it was pyritized), a n d X - r a y p h o t o g r a p h s
but not c o n f i r m e d until this study.
10
THE
BIOLOGY
OF
TRILOBITES
On m a n y trilobites there is a medial, glabellar n o d e on the
Naroidae to 40 or m o r e . Each segment has a central or axial
meraspid (juvenile) that generally disappears by the holaspid
p o r t i o n and a lateral part on each side of the body called the
(adult) phase or early in the holaspid growth. T h i s n o d e is inter-
pleura (plural, pleurae). T h e usually grooved pleurae also may
preted as having a visual or light-sensing capability ( R u e d e m a n n
extend laterally beyond the body into short rounded extensions
1 9 1 6 b , Jell 1 9 7 5 ) . Cryptolithus is a c o m m o n O r d o v i c i a n trilobite
called lappets (Plates 50 to 5 6 ) or even into m o r e extended and
genus in New York that lacked n o r m a l eyes b u t retained this
pointed pleural spines (Figure 2 . 2 C ) . T h e distinction between
median glabellar n o d e into the m a t u r e holaspis (Plates 163 to
lappets and spines is qualitative, and in s o m e cases it is not clear
1 6 7 ) . A review of the evolution of trilobite eyes with references
whether the extensions should be termed long lappets or short
for detailed reading is given by C l a r k s o n ( 1 9 7 5 ) . M o r e will be said
spines (Plates 46 and 4 8 ) . O t h e r structures can increase flexibil-
about eye function later in this chapter when the possible m o d e s
ity and s o m e t i m e s tight enrolling, but these are beyond the scope
of life of trilobites are discussed.
of this b o o k . T h e s e structures are covered in detail in the work
In p o s t - C a m b r i a n and m o s t C a m b r i a n trilobites there is a
by Bergstrom ( 1 9 7 3 ) .
suture r u n n i n g across the upper edge of the eye, separating the
T h e most posterior part of the trilobite is the pygidium
lens surface f r o m the palpebral area. T h i s suture or separation
(Figure 2 . I F ) . T h e pygidium, similar to the thorax, has segments
continues to the edge of the c e p h a l o n in b o t h directions and
with axial and pleural p o r t i o n s . However, the pygidial segments
results in a portion of the cheek area (librigena) that can separate
are totally fused so there is no flexibility a m o n g the parts. T h e
from the c r a n i d i u m . T h i s facial or cephalic suture separates the
n u m b e r of axial segments, the n u m b e r of pleurae, and the general
free cheek (librigena) f r o m the fixed cheek (fixigena).
shape of the pygidium are often diagnostic to species. Pygidia are
In most C a m b r i a n trilobites an additional suture runs below
c o m m o n in the trilobite fossil record, and these features are very
the eye and j o i n s the facial suture, f o r m i n g the c i r c u m o c u l a r
i m p o r t a n t to the identification of trilobites. T h e pygidium can
suture so that the visual surface separates on m o l t i n g and is lost.
have marginal lappets or marginal spines (Figure 2 . 2 D ) as exten-
It is also c o m m o n in articulated calymenids for the visual surface
sions of the pleurae, and s o m e t i m e s has a central posteriorly
to be missing. T h i s a b s e n c e suggests that a suture s u r r o u n d e d the
directed spine called the t e r m i n a l axial spine (Plate 8 8 ) . In addi-
visual surface or that it was weakly mineralized, if at all.
t i o n , there is s o m e t i m e s a narrow featureless area around the
T h e a n t e r i o r margin of the c e p h a l o n is rounded and the pos-
margin of the pygidium simply called the border. In s o m e genera
terior margin is less curved laterally, resulting in the f o r m a t i o n of
of trilobites, the pygidium is almost featureless, and when f o u n d
a c o r n e r at the posterolateral e x t r e m i t y k n o w n as the genal angle.
separate, it looks like n o t h i n g m o r e than a dark t h u m b n a i l on or
I )epending on the species, this structure varies f r o m a blunt well-
in the rock. T h i s finding should not be overlooked as an indica-
rounded angle to a genal spine (Figure 2 . 2 B ) that extends back
tor o f the presence o f particular species.
along the body. O n e end of the facial suture crosses the genal area
On the surface of m a n y trilobites, there are pitted areas that
and emerges o n the anterior m a r g i n o f the c e p h a l o n , and the
often penetrate the exoskeleton. T h e exoskeleton of the large
o t h e r e n d emerges either in front or b e h i n d the genal angle. If
trilobite Dipleura dekayi is literally covered with pits, seen
both ends of the sutures emerge a n t e r i o r to the genal angle, it is
Figure 2.6A as small white specks. Figure 2 . 6 B shows a broken
known as a p r o p a r i a n (Fig 2 . 5 A ) suture; if o n e end emerges on
area of this trilobite, with the pits as complete perforations
the posterior cephalic m a r g i n , the suture is called opisthoparian
through the cuticle. Isotelus gigas is similarly covered with pits
in
(Figure 2 . 5 C ) . As o n e might expect, there are trilobites where the
(Figure 2 . 6 D ) . Pits such as on these two trilobites may have served
suture emerges precisely o n , or very near, the genal angle, and that
a sensory purpose and may have contained sensory hairs. A dif-
condition is called g o n a t o p a r i a n (Figure 2 . 5 B ) . In s o m e trilobites
ferent kind of pit is seen on the cephalic border of Cryptolithus
the cephalic suture (Figure 2 . 5 D ) is fused and does not o p e n on
species (Figure 2 . 6 C ) . T h e s e are also perforations but go c o m -
molting.
pletely through the b o r d e r area. T h e i r role is u n k n o w n , but they
T h e area immediately in front of the glabella varies from
m a y have served to sense water currents or m o v e m e n t .
nearly nonexistent to a broad b o r d e r platform or b r i m . In s o m e
T h e exoskeleton covering the entire dorsal surface of the trilo-
families, particularly the calymenids (Figure 2.31), the shape of
bite s o m e t i m e s curls under at the edges of the cephalon and
this area is i m p o r t a n t to the identification of genera.
pygidium to form the doublure (Figure 2 . 7 H , I ) , a fiat terrace
S o m e t i m e s this anterior b o r d e r has a lateral furrow. T h e area
a r o u n d the ventral edges of the cephalon and pygidium. In addi-
between this preglabellar furrow and the glabellar furrow is the
tion to the d o u b l u r e , there are two important pieces of the
preglabellar field (Plates 139 a n d 1 4 2 ) . T h e area between the
exoskeleton on the ventral side of the cephalon. T h e rostral plate,
preglabellar groove and the a n t e r i o r margin
is the a n t e r i o r
cephalic border.
found on m a n y but not all trilobites, is a c o n t i n u a t i o n of the d o u blure b u t is separated from the rest of the cephalon by sutures; it
T h e t h o r a x is divided into a n u m b e r of segments that f o r m a
is located directly under the front central part of the cephalon
highly flexible part o f the exoskeleton. T h e n u m b e r o f t h o r a c i c
(Plate 65 shows a displaced rostral plate immediately in front of
segments can range from zero in the unusual C a m b r i a n family
the c e p h a l o n ) . Under the a p p r o x i m a t e center of the cephalon is
FIGURE 2.6.
Exoskeletal pits or circular perforations. A. Dipleura dekayi(PR\ 4 9 6 2 9 ) . White s p e c k s over
the b o d y are sediment-filled pits. The arrow points to the area s h o w n in B. B. C l o s e - u p of Dipleura pits, showing
that they e x t e n d
through
the
exoskeleton
(arrow).
C.
Cryptolithus
lorettensis (PRI
49657,
whitened), s h o w i n g pits on the c e p h a l i c border (arrow). These are actually perforations that e x t e n d all the way through the border. D. Isotelus gigas (TEW collection, w h i t e n e d ) . The exoskeleton' is heavily pitted (arrow),
a d i a g n o s t i c character of this s p e c i e s .
E.
Greenops grabaui (F.
Barber collection,
whitened), s h o w i n g rows of circular perforations characteristic of the New York a s t r o p y g i d s . F. Greenops? species (GJK collection, w h i t e n e d ) . U n n a m e d , new?, s p e c i e s of Greenops in w h i c h the circular perforations are d e g e n e r a t e .
12
THE
BIOLOGY
OF
TRILOBITES
FIGURE 2.7. Ventral a n a t o m y of the exoskeleton. A-D.
Ceraurus pleurexanthemus
(PRI
49658,
whitened), p r e p a r e d to show the ventral exoskeleton. B. The h y p o s t o m e (arrow). C. Two of the a p o d e m e s (arrows). The a p o d e m e s are a r r a n g e d along the ventral surface u n d e r the axial furrow. There is a pair of a p o d e m e s for e a c h pair of c e p h a l i c a p p e n d a g e s , two for e a c h pair of thoracic a p p e n d a g e s ( w h i c h also c o r r e s p o n d to the n u m b e r of thoracic s e g m e n t s ) , a n d a p o d e m e s a s s o c i a t e d with the p y g i d i a l a p p e n d a g e s . The often large n u m b e r s of pygidial a p p e n d a g e s are not as well reflected in prominent a p o d e m e s . D. The arrows point out the entrance into the hollow exoskeletal genal spines, pleural s p i n e s , a n d pygidial spines. E-l. Isotelus s p e c i e s (Kevin Brett collection), ventral exoskeletal anatomy. A s p e c i m e n from C a n a d a . F. The h y p o s t o m e (arrow), the anterior m a r g i n a n d " w i n g s " of w h i c h are under the d o u b l u r e . G. The a p o d e m e s (arrows) of Isotelus, w h i c h are far less prominent than t h o s e of Ceraurus. Given that these represent m u s c l e a t t a c h m e n t , the shape must represent their use a n d consequently the life-mode of the trilobite. H. The cephalic d o u b l u r e (arrow). I. The p y g i d i a l doublure (arrow), w h i c h is i n c o m p l e t e in this specimen.
a
rounded plate called the h y p o s t o m e
(plural, h y p o s t o m a )
(Figure 2 . 7 B , F ) . T h e m o u t h was a t the rear o f the h y p o s t o m e . T h e h y p o s t o m e is a m o r e i m p o r t a n t feature. F o r s o m e species
T h e a t t a c h m e n t of the h y p o s t o m e is proposed to have significance for the h i g h - o r d e r classification of trilobites (Fortey [1990a]
using observations
m a d e by Fortey and C h a t t e r t o n
it is very robust, distinctive, and a not u n c o m m o n part of the
[ 1 9 8 8 ] ) . Natent h y p o s t o m a are those separated from the cephalic
fossil record. (In at least o n e rare O r d o v i c i a n trilobite, Hypodi-
d o u b l u r e , or rostral plate when present, by a gap and are dis-
cranotus, the presence of its h y p o s t o m e is a very g o o d indicator,
placed or absent in m o s t trilobite specimens. C o n t e r m i n a n t
and o n e o f the only indicators, o f its stratigraphic range.) T h e
h y p o s t o m a are closely j o i n e d to the cephalic d o u b l u r e or rostral
significance of the h y p o s t o m e will be pointed o u t for the indi-
plate and consequently are m o r e likely to be present on speci-
vidual species. T h e h y p o s t o m e is directly under the glabella, and
m e n s (Figure 2 . 7 B , F ) . In both of the above cases, the anterior
together they f o r m an envelope covering and protecting the
margin of the glabella is directly above the anterior margin of the
s t o m a c h . T h e m o u t h of the trilobite was at the posterior central
h y p o s t o m e . T h e third type of h y p o s t o m e , i m p e n d e n t , is when
n o t c h of the h y p o s t o m e (Plates 3 7 , 4 7 , 77, 117, 153, and 1 5 7 ) .
the anterior margin of the h y p o s t o m e is not close to the anterior
13
ONTOGENY margin of the glabella and the anterior margin of the glabella
O n e needs very sharp eyes to spot t h e m a m o n g the n o r m a l fossil
coincides with the cephalic margin. Examples of trilobites with
debris, or to spend hours with a s t e r e o m i c r o s c o p e scanning likely
the different types of h y p o s t o m e a t t a c h m e n t are as follows:
surfaces. M o s t protaspides that have been studied are those in
n a t e n t — s o m e proetids; c o n t e r m i n a n t — / . gigas (Plates 153 and
which their exoskeletons have been replaced by silica, since silici-
155)
fied fossils survive acidic dissolution of a limestone or shaly
£.
and
Cerauruspleurexanthemus
(Plate
77);
and
impendent—
rana.
m a t r i x . O n e then uses the m i c r o s c o p e to pick out the important
Under the lateral sides of the ventral axial region of the t h o -
material f r o m the insoluble residue, including protaspides. T h e
racic segments, glabella, and pygidium are thickened areas called
advantage of this procedure is that in silicified material, very fine
apodemes (Figure 2 . 7 C , G ) o r s o m e t i m e s a p p e n d i f e r s . T h e a p o -
details, including spines and in s o m e cases h y p o s t o m a , are often
demes are believed to have been points of muscle a t t a c h m e n t and
preserved.
may provide evidence for the lifestyle of the trilobite. On s o m e trilobites,
such
as
Ceraurus
pleurexanthemus
(Plate
77),
T h e shape and o t h e r physical features of the protaspis are
the
u n i q u e for specific fossil families and genera, and for this reason
apodemes extend down from the ventral surfaces of the segments
the protaspides are used for t a x o n o m i c assignments and confir-
to form p r o m i n e n t ridges or posts, yet in others, as illaenids, the
m a t i o n ( C h a t t e r t o n and Speyer 1 9 9 7 ) . Protaspides are assigned
apodemal area is fairly s m o o t h . T h e long a p o d e m e s suggest g o o d
to specific trilobites a n d growth series through association with
leverage for the attached muscles and a high level of l i m b m o b i l -
pieces of the m o r e m a t u r e fossil in the same debris and through
ity, perhaps for s w i m m i n g , rapid crawling, or digging.
the prior knowledge of protaspis-adult relationships. Using the presence of m a t u r e trilobites, however, is not always a secure way to assign protaspis-adult relationships.
Ontogeny
It is p r o b a b l e that the pre-protaspid and protaspid phases of
O n t o g e n y is the biological life cycle of an animal; for the trilo-
the trilobite growth cycle served to disperse the trilobites in their
bite this would be from the presumed egg to the smallest larvae
e n v i r o n m e n t , similar to the situation with m a n y m o d e r n m a r i n e
and the various intermediate stages, to the end of its life cycle.
Crustacea. S o m e protaspides were benthic ( b o t t o m dwelling) and
Considerably m o r e is k n o w n about the adult phase of the trilo-
others planktic (in the p l a n k t o n ) , drifting in the Paleozoic seas.
bite life cycle because the vast p r e p o n d e r a n c e of the fossil record
Because o f their differing l i f e - m o d e and preservation, s o m e p r o -
is c o m p o s e d of the pieces of the exoskeleton representing late
taspides m a y never be f o u n d or never be associated with their
growth stages. Careful workers have f o u n d , however, a significant
later growth and adult phases.
a m o u n t of i n f o r m a t i o n related to trilobites' earlier growth stages.
Parts B and C in Figure 2.8 show two protaspides of trilo-
Chatterton and Speyer ( 1 9 9 7 ) provide an extensive and current
bites f r o m the Lower D e v o n i a n of New York. T h e o n e in B is a
review of the present state of knowledge of trilobite ontogeny.
lichid (family Lichidae) and the o n e in C is a phacopid (family
Trilobites most likely began life as an egg, which was either laid
P h a c o p i d a e ) . T h e y are magnified to the s a m e scale and each is
outside the body or hatched within the a n i m a l , although there is
a b o u t a m i l l i m e t e r in actual length. At this phase of growth,
no unequivocal evidence of trilobite eggs. C. D. Walcott ( 1 8 7 7 c ) ,
morphological
in a study of remarkably well-preserved trilobites in New York,
in the adult, are given the profo-prefix. T h u s , the protaspis has a
features, which
represent
a
future body part
found spherical objects within the cross sections of s o m e trilo-
protocephalon,
bites, which he identified as eggs. T h i s and earlier reports a b o u t
adults, and a p r o t o p y g i d i u m . Trilobites also had growth stages
described
similarly
to
the
cephalon
of the
trilobite eggs by Barrande in 1852 apparently have not been inves-
within the protaspid phase. T h i s is observed by increases in the
tigated completely.
n u m b e r of lateral lobes on the glabellar axis and the general size
T h e well-defined phases of trilobite growth are labeled the
(Figure 2 . 8 A ) . T h e p r o t o c e p h a l o n and p r o t o p y g i d i u m , however,
protaspid, meraspid, and holaspid phases. Fortey and M o r r i s
are fused and r e m a i n together in the molted protaspid exoskele-
Lower
ton, although the free cheeks and the h y p o s t o m e may be deta-
Ordovician as a pre-protaspid phase of trilobite called phaselus.
c h e d . Each successive molt is called an instar (Figure 2 . 8 A ) .
Chatterton and Speyer ( 1 9 9 7 ) also found phaseluses in beds with
W h e t h e r or not there is a direct correlation between the n u m b e r
silicified trilobite remains. It is still not clear whether these are
of instars and the n u m b e r of m o r p h o l o g i c a l l y defined phases is
from trilobites or a n o t h e r fossil a r t h r o p o d .
not clear.
(1978)
described
some
small
exoskeletons
from
the
T h e first well-defined phases in growth of the trilobite, after
W h e n the trilobite larvae clearly begin to display the separa-
the presumed egg and the phaselus, is the protaspid phase. ( T h e
tion of the p r o t o c e p h a l o n f r o m the p r o t o p y g i d i u m , they are
name protaspis (plural, protaspides)
was given to the individual
referred to as being in the meraspid phase (Figure 2 . 8 E ) . T h e
silicified exoskeletons found in or on rocks by C. Beecher ( 1 8 9 3 a ,
segments develop from the anterior of this transitory pygid-
1893b).) Protaspides are difficult to find because of their small
i u m . ( O n c e the s e g m e n t a t i o n is definite, the protopygidium is
size. T h e larger ones are about the size of the " o " in the printed
no longer " p r o t o " but is still not the final pygidium, as the t h o -
word "protaspis," and m o s t are between that a n d h a l f that size.
racic segments are being f o r m e d anterior to this new pygidial
FIGURE 2.8.
O n t o g e n y of the trilobite. A. Flexicalymene senaria p r o t a s p i d e s from the O r d o v i c i a n of New York. These silicified s p e c -
imens w e r e p r e p a r e d a n d reported on by Chatterton et al. (1990). R e p r o d u c e d with p e r m i s s i o n . B. Possibly a lichid protaspid from the w o r k of B e e c h e r (1893a) a n d r e p r o d u c e d by Whittington (1957). C. A p h a c o p i d p r o t a s p i d from the s a m e source as B. D. The p r o t a s p i d of Isotelus gigas reported on by Chatterton a n d Speyer (1990). R e p r o d u c e d with permission. The s h a p e p r e c l u d e s this p r o t a s p i d from b e i n g a b o t t o m dweller. It p r o b a b l y w a s planktic, living a n d drifting near the surface of the sea. E. Triarthrus m e r a s p i d instars of d e g r e e 1, 2, a n d 4 from Whittington (1957). This is part of a nearly c o m p l e t e g r o w t h series c o l l e c t e d a n d reported on by Walcott (1918). The m e r a s p i d e s are r e p r o d u c e d at a b o u t eight times their life size. F. A growth series of Isotelus gigas holaspides from R a y m o n d (1914). The h o l a s p i d s are natural size. Young Isotelus h o l a s p i d e s have prominent genal s p i n e s , w h i c h are lost, in New York s p e c i m e n s , w h e n they r e a c h a b o u t 5 0 m m l o n g . G. A molting s e q u e n c e for c a l y m e n i d trilobites p r o p o s e d by Mikulic a n d Kluessendorf (2001). The trilobite on the right first p u s h e s its p y g i d i u m into the surface as an anchor, the c e p h a l i c sutures o p e n , and the animal c r a w l s f o r w a r d a n d out. The c e p h a l i c parts held in position by the ventral integument fall b a c k together, leaving a molt with the c e p h a l o n a n d p y g i d i u m c u r v e d d o w n w a r d a n d the thorax in a c o n c a v e curve d u e to the p u s h i n g up of the c r a n i d i u m during the p r o c e s s .
15
ONTOGENY s t r u c t u r e — h e n c e , the n a m e transitory pygidium.) In trilobites the
125 mm
early meraspides show a line of separation f r o m the cephalon on
Trenton age rocks of New York.
(5
inches)
are c o m m o n
in
the
Middle Ordovician
the anterior margin of the transitory pygidium but no t h o r a c i c
As in all a r t h r o p o d s , growth in trilobites required that the
segments. This is referred to as a "degree 0 meraspis." D u r i n g suc-
exoskeleton be shed or molted at regular intervals. In modern
cessive molts, as the segments detach from the transitory pygid-
a r t h r o p o d s , m o l t i n g (ecdysis) begins by the f o r m a t i o n of a new
ium and can be considered separate, the meraspis grows in size
cuticle or shell beneath the current o n e , separation of these shells
and degree number. Each detached t h o r a c i c segment is c o u n t e d ,
by a space filled with m o l t i n g fluid, and resorption of much of
and this n u m b e r is the degree assigned to the meraspis. T h e fact
the old cuticle to provide the base chemicals to finish the new
that segments are added from the anterior side of the transitory
o n e . W h e n this process is c o m p l e t e , the old shell splits and
pygidium is ascertained by the growth of trilobites with pleural
the animal emerges with a soft cuticle in place. By swelling this
or axial spines on specific t h o r a c i c s e g m e n t s . T h e spine first
soft cuticle through the intake of liquids, the new body rapidly
appears on a segment adjacent to the transitory pygidium, and
b e c o m e s larger. T h e new exoskeleton then hardens and the
each succeeding segment is added behind it
animal has grown o n e m o r e i n c r e m e n t . Because o f the resorption
until the adult
n u m b e r of segments is reached. There are usually p r o f o u n d changes in the shape of the
of s o m e of the old cuticle, the molted shell is significantly thinner and m o r e fragile than it was on the a n i m a l . T h i s process also
cephalon during the meraspid phase. W h e n the meraspid trilo-
lowers the energy r e q u i r e m e n t s of growth because the resorbed
bite molted, the cephalon and transitory pygidium separated, and
chemicals are available for the new exoskeleton.
thus they are found as distinct e l e m e n t s , unlike the o n e - p a r t p r o -
Trilobite molts, on the o t h e r h a n d , are robust and at least as
taspis molts. T h e meraspis can grow until it gains the n u m b e r of
thick as m o l t s attributed to living a n i m a l s that died and were pre-
free thoracic segments f o u n d in the adult, at which t i m e it is
served. T h i s i n f o r m a t i o n indicates that trilobites did not resorb a
called a
significant a m o u n t o f the minerals o f the old exoskeleton and
holaspis.
Figure 2.8E illustrates a limited growth series of Triarthrus
must have e m e r g e d from the m o l t i n g process with a rather thin
eatoni, part of the only nearly c o m p l e t e series k n o w n from a New
cuticle that was little m o r e than a soft template within which the
York trilobite. T h e meraspides appear to be missing their free
new mineralization t o o k place. Very thin a n d compressed or
cheeks and are probably molts. Meraspids are also k n o w n for
wrinkled trilobite fossils are k n o w n and usually are attributed
Elliptoccphala asaphoides from
the Lower C a m b r i a n of New York
to the exoskeletal remains or impressions of recently molted or
(Ford 1877, 1 8 7 8 ) , but articulated holaspids are rare. Parts D and
" s o f t - s h e l l e d " individuals. T h e r e is at least o n e e x a m p l e of a trilo-
F of Figure 2.8 illustrate the m o r p h o l o g i c a l changes in Isotelus
bite preserved in the Burgess Shale beds that is completely
gigas from the protaspid (Figure 2 . 8 D ) through the early holaspid
unmineralized and believed to be a very recently molted individ-
(Figure 2 . 8 F ) . It is surprising, given the n u m b e r of adult trilobite
ual ( W h i t t i n g t o n 1 9 8 5 ) . T h i s finding suggests that trilobites were
remains found in New York, that so few examples of growth series
vulnerable to predators and external t r a u m a for an extended time
have been recorded. Either the exoskeleton on the juvenile f o r m s
and that building the new exoskeleton required significant energy
of most trilobites is too fragile and not easily preserved in the
from the a n i m a l . It also suggests that as trilobites gained size, they
fossil record, or the juveniles did not o c c u p y areas where their
b e c a m e increasingly vulnerable d u r i n g m o l t i n g and that the
remains could be readily preserved or f o u n d .
n u m b e r of trilobites that might grow to an exceptional size for
T h e trilobite exoskeleton did not necessarily b e c o m e fixed in
the species was severely limited. Early trilobite predators such as
its physical structure at the early holaspid phase. T h e achieve-
Anomalocaris species have been identified in the Middle C a m -
ment of the holaspid phase generally only m e a n s that no m o r e
brian, and the n u m b e r of potential predators such as cephalopods
thoracic segments were added during c o n t i n u e d growth. T h e r e
and fish increased t h r o u g h o u t the Paleozoic.
are, however, variations in the n u m b e r of t h o r a c i c segments in
T h e r e are m a n y possible strategies for trilobite molting, and
the holaspis of a very few species; in Aulacopleura koninki, from
the cephalic sutures play a part in m o s t of t h e m . H e n n i n g s m o e n
the Silurian of B o h e m i a , t h o r a c i c segments were added after the
( 1 9 7 5 ) , M c N a m a r a and Rudkin ( 1 9 8 4 ) , Speyer ( 1 9 8 5 , 1990b,
holaspid phase was reached ( H u g h e s and C h a p m a n 1 9 9 5 ) . F o r
1 9 9 0 c ) , and W h i t t i n g t o n ( 1 9 9 2 , 1 9 9 7 ) discussed specific molting
all other trilobites the segment n u m b e r was stable. Trilobites did
strategies in detail.
not reach maturity, or at least their final body p r o p o r t i o n s , until
fossils in m a n y New York rocks. S i n c e m o s t of these parts are
they grew substantially from the first holaspis. In s o m e trilobites
attributable to molts, significant i n f o r m a t i o n is gained from their
such as Eldredgeops species, the growing holaspis changed very
e x a m i n a t i o n . For e x a m p l e , in Eldredgeops rana, the very c o m m o n
little and the small ones looked essentially like the adults. Isotelus
trilobite of the Middle Devonian of New York, c o m p l e t e cephala
gigas, on the other hand, possessed long genal spines in meraspids
and pygidia are the parts most often f o u n d . T h i s evidence shows
and early holaspides (Figure 2 . 8 F ) and did not lose the spines
that the facial sutures were fused and that the c o n n e c t i o n s
until it reached about o n e - t h i r d the size of a full m a t u r e speci-
between the cephalon and thorax and between the thorax and
men. Isotelus tergites or molt remains from specimens longer than
pygidium were o p e n e d or weakened during the molting process.
Disarticulated exoskeletons are c o m m o n
THE
16 T h e a n i m a l generally emerged through the split between the cephalon and t h o r a x .
BIOLOGY
OF
TRILOBITES
spine is on the lower lamella. An articulated specimen of Cryptolithus without the genal spines can be reasonably assumed to be
O n e often-illustrated set of molt remains is the upright t h o r a x
a molt (Plates 163 and 1 6 5 ) . In s o m e extant arthropods like the
and pygidium, with the inverted c e p h a l o n just in front of it. In
h o r s e s h o e c r a b , however, which uses this same molting technique,
this case the molting animal must have pushed forward after the
the suture can reseal after m o l t i n g and the molted exoskeleton
cephalon and t h o r a x parted, with the forward margin of the
remains whole. T h u s , when o n e finds a whole, articulated Cryp-
cephalon pushed down in the s e d i m e n t . T h i s action would pivot
tolithus s p e c i m e n with
the cephalon molt over upside d o w n , and the a n i m a l could then
absolute certainty it is not a molt.
its genal spines, o n e c a n n o t say with
emerge with the thorax and pygidium almost intact and right
M o s t authors agree on the generalities of trilobite molting, but
side up. That the pygidium is usually f o u n d separate suggests that
s o m e unanswered questions are rarely discussed. T h e roles of the
the c o n n e c t i o n is weakened d u r i n g the m o l t i n g process a n d
ventral, unscleritized i n t e g u m e n t and the scleritized appendages
s o m e t i m e s separates f r o m the t h o r a x d u r i n g or shortly after
have been largely ignored ( b u t see W h i t t i n g t o n 1 9 9 2 ) . It is not
ecdysis. T h e r e are other a r r a n g e m e n t s , besides the o n e just dis-
surprising that there is little preserved evidence for the ventral
cussed, of the m o l t remains of E. rana f o u n d in western New
m e m b r a n e ; there is so little soft tissue evidence from the fossil
York. S. E. Speyer ( 1 9 9 0 c ) , w h o has studied these m o l t r e m a i n s ,
record, and only o n e of the k n o w n soft tissue preservation sites
s u m m e d it up well: "Trilobites, like m o d e r n a r t h r o p o d s , displayed
contains any significant ventral anatomical information beyond
a variety of m o u l t behaviors which vary according to ecological
the appendages (Walcott 1 8 8 1 , 1 9 1 8 ) . In the trilobites in which
considerations (e.g., substrate consistency) and individual c o n v e -
the loss of the free cheeks is an i m p o r t a n t first step in ecdysis, the
nience."
inversion of these parts helps d e m o n s t r a t e the actual process
M o s t other trilobites, however, lose their free cheeks during
( M c N a m a r a and Rudkin 1 9 8 4 ) . B r i e f m e n t i o n is m a d e of the pos-
the m o l t i n g process. T h e most c o m m o n fossil remains of /. gigas,
sibility that the free cheeks m a y still have been attached to the
for e x a m p l e , are cranidia, free cheeks, h y p o s t o m a , and pygidia.
ventral m e m b r a n e and would have been inverted as they c a m e
Separated
specimens
away f r o m the a n i m a l . M c N a m a r a and Rudkin as do others,
without their free cheeks are very rarely f o u n d in the fossil record.
explain the inversion of the cephalon in molt remains as evidence
/. gigas evidently molted by the facial sutures o p e n i n g and the
that the trilobite pushed its cephalon down in front while arch-
whole
cephala
of Isotelus, or articulated
free cheeks separating, with the suture between the c r a n i d i u m
ing its t h o r a x to break away the cephalon at the c e p h a l o t h o r a x
and the d o u b l u r e o p e n i n g , possibly along with a break in the c o n -
suture. As the trilobite c o n t i n u e d to m o v e forward, the cephalon
nection between the t h o r a x and the c e p h a l o n . T h e s e breaks per-
inverted. M a n y trilobites are f o u n d with the inverted cephalon
mitted ecdysis by the trilobite m o v i n g straightforward. T h i s
under the t h o r a x . M a n y of these also have long genal spines.
molting strategy is i m p o r t a n t because /. gigas in the early phase
S o m e trilobite genal spines are totally enclosed except for the
had quite long genal spines, and it had to be able to free t h e m
area at the genal angle. For this m e c h a n i s m to take place, the soft
to molt properly. T h e m o s t efficient way to do this was to
spines must be dragged from their exoskeleton prior to total
emerge in a forward direction through the o p e n e d sutures in the
inversion of the free cheeks. Such a m e c h a n i s m is illustrated by
cephalon.
W h i t t i n g t o n ( 1 9 9 2 , Figure 9 ) . Not illustrated is the final struggle
Spines on the trilobites were hollow, and the tissue inside had to be withdrawn during m o l t i n g (Figure 2 . 7 D ) . Any m o l t i n g
of the a n i m a l during the ecdysis process, which drags the dorsal cuticle forward over the now-inverted free cheeks.
strategy of an individual trilobite must a c c o m m o d a t e the phy-
Based on the observation that calymenid trilobites from the
sical shape of the a n i m a l . Since the newly m o l t e d a n i m a l was
Silurian of W i s c o n s i n and Illinois are often found with the
unmineralized and soft, there must have been s o m e strategy to
cephalon and pygidium curled somewhat down, with a distinct
provide s o m e protection while the new exoskeleton b e c a m e suit-
concave sway to the t h o r a x , Mikulic and Kluessendorf ( 2 0 0 1 )
ably mineralized and hardened.
p r o p o s e that the trilobite molted by pushing its pygidium into
It is not always possible to distinguish the m o l t e d parts from the disarticulated
remains
of a
dead
trilobite.
A
complete
the substrate to a n c h o r it, by the sutures between the free cheeks and c r a n i d i u m as well as the anterior cephalic suture o p e n i n g ,
exoskeleton, with free cheeks, is almost always the fossil of the
and by the animal crawling forward, leaving the old exoskeleton
carcass of a trilobite. As in any rule, however, there are exceptions.
b e h i n d . T h e y further propose that since the upper and lower p o r -
Trinucleids and harpids do not have dorsal facial sutures. T h e
tions of the cephalon are held in place by the ventral integument,
dorsal cheeks and preglabellar areas are separated from the
after the m o l t i n g process the parts fall back into place, leaving a
ventral d o u b l u r e by a suture that runs parallel to the horizontal
molt that may be indistinguishable from a carcass (Figure 2 . 8 G ) .
plane. In o t h e r words, there is a suture separating the dorsal
T h e same process is seen in extant horseshoe crabs, which leave
surface from the ventral surface, and the suture line is a r o u n d the
behind an intact m o l t e d exoskeleton.
edge o f the c e p h a l o n . M o l t i n g o c c u r s b y the o p e n i n g o f this
G r o w t h was rapid during the early holaspid phase and could
suture and the trilobite emerging forward. In trinucleids the genal
be expected to slow as the animal reached maturity. In a few rare
SOFT
BODY
PARTS
17
cases, long periods between molts of larger individual species have been inferred. Tetreault ( 1 9 9 2 ) , Kloc ( 1 9 9 3 ,
only five localities worldwide, including the really remarkable
1 9 9 7 ) , and
new C a m b r i a n sites in C h i n a ( S h u et al. 1 9 9 5 ) . Two of these five
Brandt ( 1 9 9 6 ) observed epizoans (encrusting a n i m a l s ) on whole,
sites are in New York and o n e of t h e m , the Walcott-Rust Quarry,
articulated exoskeletons of several species of trilobites.
Such
was not included in Briggs and Allison's list. I n f o r m a t i o n on soft
encrusters must have been on the living a n i m a l , as articulated
or weakly skeletonized b o d y parts is very rare, and because of this
trilobites would not remain whole unless buried a very short t i m e
these data are generalized to a wide range of trilobites. T h e rarity
after death and epizoans would have little o p p o r t u n i t y to b e c o m e
of this s o f t - b o d i e d i n f o r m a t i o n is exemplified by the remarkably
attached to the buried carcass. T h e s e observations indicate either
preserved biota of the Burgess Shale in British C o l u m b i a . Most
a terminal molt, after which there is little growth in the animal
of what is k n o w n of s o f t - b o d i e d a n i m a l s in the C a m b r i a n initially
with no further molting, or long intervals between molts of the
c a m e f r o m these beds, yet of the 22 species of trilobites k n o w n
mature species. Tetreault further observed that b r a c h i o p o d s on
from the Burgess Shale beds, apparently only 4, so far, have
the exoskeleton of Arctinurus boltoni were in
four distinct size
yielded appendage i n f o r m a t i o n and in o n e of these it is from a
classes.
F r o m this he d e d u c e d , a s s u m i n g these b r a c h i o p o d s
single s p e c i m e n . W h e n you are reading through the following
spawned o n c e a year, that the largest b r a c h i o p o d s were 4 years
descriptions, r e m e m b e r that all the soft tissue data c o m e from a
old and that in m a t u r e Arctinurus animals m o l t i n g was terminal
very few sites and only a bare handful of trilobite species.
or occurred at as m u c h as 4-year intervals.
An indirect relationship of trilobites to the annelid w o r m s was
Many collectors find populations of trilobites that are signi-
introduced earlier. T h i s evolutionary trail is s u p p o r t e d by the
ficantly larger than the n o r m . Excellent s p e c i m e n s of E. rana 5
m u l t i s e g m e n t e d b o d y o f the trilobite a n d the observation that
to 6 . 4 c m (2 to 2.5 inches) long and /. gigas 13 to 1 5 c m (5 to
each recognizable s e g m e n t bears a pair of appendages. This
6 inches) long are not u n c o m m o n . S p e c i m e n s of E. rana of 10 to
observation includes the c e p h a l o n and pygidium, in which the
13 cm (4 to 5 inches) and 7. gigas of 3 0 . 5 cm ( 1 2 inches) and larger
segments are fused. Careful studies, by C. D. Walcott ( 1 8 7 6 , 1 8 8 1 ,
are found, but rarely. T h e largest reported articulated trilobite is
1918, 1 9 2 1 ) , of the s p e c i m e n s he had available established that
an Ordovician asaphid from the Arctic. It is 72 cm ( 2 8 inches)
the appendages are b i r a m o u s (Figure 2 . 1 0 A ) . In o t h e r words,
long.
growth
each individual appendage is divided into two parts, o n e part for
throughout life, as do extant lobsters, and could achieve an excep-
walking, the e n d o p o d (Figure 2 . 1 0 D ) , and o n e part, the e x o p o d
This
indicates
that
some
trilobites
continued
tional size in favorable e n v i r o n m e n t s . R a y m o n d ( 1 9 3 1 ) , describ-
(Figure 2.1 OB), possibly an apparatus similar to the gill of fishes,
ing an unusually large h y p o s t o m e of an Isotelus species from the
for breathing.
Ordovician Chazy limestones, estimated the length of the trilo-
T h e o n l y trilobite appendages that are not b i r a m o u s are the
bite at 61 to 6 4 c m ( 2 4 to 26 i n c h e s ) . Estimates of sizes of o t h e r
most anterior, which are modified into a n t e n n a e (Figure 2 . 1 1 A ,
New York trilobites, from molt remains or partial s p e c i m e n s ,
B , C ) . C . E . B e e c h e r ( 1 8 9 3 c , 1 8 9 4 a , 1 8 9 4 b , 1 8 9 6 ) , after years o f
listed by R a y m o n d are as follows:
study on meticulously prepared Triarthrus eatoni from Beecher's Trilobite Bed, published the m o s t f a m o u s , and m o s t often re-
Basilicas Isotelus Isotelus Isotelus Terataspis Trimerus Coronura
whittingtoni "giganteus" gigas maximus grandis major myrmecophorus
- 1 2 inches
(30 cm)
- 2 4 - 2 6 inches
(61-64 cm)
2 . 1 1 A ) . Beecher, possibly following Walcott's lead, gave T. eatoni
- 1 7 inches
(43 c m )
an extra set of appendages u n d e r the c e p h a l o n , but this does not take away from his r e m a r k a b l e a c h i e v e m e n t .
p r o d u c e d , illustration of the trilobite ventral a n a t o m y (Figure
- 1 8 - 1 9 inches
(46-48 cm)
- 2 0 - 2 4 inches
(51-61 cm)
- 1 5 - 1 6 inches
(38-41 cm)
and
- 1 5 inches
(38 c m )
Raymond
T h e works o f Walcott a n d o f Beecher have been modified augmented
by a
(1920a),
number
Stormer
of later workers,
(1939,
1951),
particularly
Sturmer
(1970),
B e r g s t r o m ( 1 9 6 9 , 1 9 7 2 , 1 9 9 0 ) , B e r g s t r o m and Brassel ( 1 9 8 4 ) ,
Soft Body Parts
Cisne ( 1 9 7 5 , 1 9 8 1 ) , W h i t t i n g t o n ( 1 9 8 0 , 1 9 9 2 ) , and W h i t t i n g t o n and A l m o n d ( 1 9 8 7 ) .
T h e unmineralized or soft parts of the trilobite b o d y are very
B i r a m o u s appendages are also the rule in extant crustaceans.
rarely preserved in the fossil record. Allison and Briggs ( 1 9 9 3 )
In the trilobites all the appendages, with the exception of the
made a listing of sites of exceptional fossil preservation, called by
a n t e n n a e , are very similar, differing primarily in size. All but o n e
the G e r m a n n a m e Konservat-Lagerstatten. T h e y recognized 19
of the trilobites recently studied have three pairs of b i r a m o u s
marine sites worldwide in the Paleozoic, where soft b o d y fossils
appendages in the c e p h a l o n , a pair for each thoracic segment,
are preserved. Nine of these sites are in the United States, and six
and multiple pairs in the pygidial section. Four pairs of b i r a m -
of them yield trilobites. O n l y o n e site in the United States in their
ous cephalic appendages reportedly were f o u n d in o n e trilobite
listing has significant trilobite appendage and o t h e r soft body
( B e r g s t r o m and Brassel
information: Beecher's Trilobite Bed in New York. In fact, most
finding is q u e s t i o n a b l e . In the pygidium the segmentation has to
of what we know about the soft parts of trilobites c o m e s f r o m
be inferred. For e x a m p l e , the n u m b e r of appendage pairs under
1 9 8 4 ) , b u t s o m e workers think this
FIGURE 2.9. Trilobite exoskeletons with a t t a c h e d f a u n a or injury. A. Arctinurus boltoni (USNM 449453). This trilobite has b r a c h i o p o d s of different sizes (arrows) a t t a c h e d , indicating the length of time b e t w e e n molts of mature s p e c i m e n s . Arctinurus s p e c i m e n s with a t t a c h e d b r a c h i o p o d s are not rare in the Rochester Shale b e d s , where these c a m e from. It is unlikely that they settled on the exoskeleton after death b e c a u s e the exoskeleton w o u l d have to have b e e n b u r i e d to remain a r t i c u l a t e d . B. The s a m e s p e c i e s of trilobite as in A with healed injuries to the exoskeleton. Three areas (arrows) have b e e n d a m a g e d a n d b e e n t h r o u g h at least one molt (PRI 42095). C. Dalmanites limulurus (F. Barber collection, w h i t e n e d ) . This trilobite has a t t a c h e d b r a c h i o p o d s (arrows). This b r a c h i o p o d a t t a c h m e n t is very unlikely to have o c c u r r e d p o s t m o r t e m for the s a m e reasons. D. The s a m e trilobite as in C, with the eye area e n l a r g e d to better s h o w the b r a c h i o p o d s (arrow). E. The s a m e trilobite, with the thoracic area e n l a r g e d to s h o w the b r a c h i o p o d s (arrows).
FIGURE 2.10.
Trilobite a p p e n d a g e reconstruction a n d n o m e n c l a t u r e . A - l . Triarthrus eatoni b i r a m o u s
a p p e n d a g e after Starmer (1939). B. The exite or brachial a p p e n d a g e (arrow) with the c o m b l i k e structures. C. The basis (arrow), also c a l l e d the coxite in early literature. D. The w a l k i n g leg or t e l e p o d i t e (arrow). This leg has seven s e g m e n t s , i n c l u d i n g the foot, in all trilobites w h e r e the a p p e n d a g e s have b e e n s t u d i e d . E. A p o d o m e r e or individual s e g m e n t (arrow) of the w a l k i n g leg. F. Endites (arrows), small triangular i n w a r d i n g - f a c i n g projections on the p o d o m e r e . T h e s e w e r e possibly u s e d to help transport f o o d a l o n g to the mouth at the rear of the h y p o s t o m e . G. Setae (arrow), hairlike projections on the exites. H. G n a t h o b a s e s (arrow) are s h a r p projections on the basis that may have b e e n used to masticate, to r e d u c e the size of f o o d particles. I. The foot (arrow) with its setae. J. A r e c o n struction of the filaments of the e x o p o d of Ceraurus pleurexanthemus by Starmer (1939). K. A partial axial view, looking toward the rear, of Triarthrus as r e c o n s t r u c t e d by Whittington a n d A l m o n d (1987, p. 42, Fig. 43). R e p r o d u c e d with p e r m i s s i o n .
20
THE
BIOLOGY
OF
TRILOBITES
FIGURE 2 . 1 1 . Ventral anatomy a n d a p p e n d a g e s . A.
Triarthrus eatoni, ventral
anatomy. The first essentially correct reconstruction of a trilobite's ventral s u r f a c e a n d a p p e n d a g e s . After B e e c h e r (1896). B. Ceraurus
pleurexanthemus,
ventral
anatomy.
This reconstruction from R a y m o n d (1920a) w a s from cross sections m a d e by Walcott in the late 1900s. C. Ceraurus pleurexanthemus,
ventral
anatomy.
This
reconstruction by Stormer (1951) w a s from s p e c i m e n s c o l l e c t e d b y Walcott a n d uniquely p r e p a r e d . D.
Triarthrus eatoni, a p p e n d a g e
structure d e v e l o p e d by Cisne (1975, p. 4 9 , Fig. 3) from high-resolution r a d i o g r a p h s of pyritized s p e c i m e n s . R e p r o d u c e d from Fossils a n d Strata, www.tandf.no/fossils, by J. L. Cisne, 1975, vol. 4, 4 5 - 6 3 , by permission of Taylor a n d Francis AS. E. Triarthrus eatoni,
a p p e n d a g e structure
d e v e l o p e d b y Whittington a n d A l m o n d (1987, p. 3 1 , Fig. 41), from direct o b s e r v a t i o n of very carefully p r e p a r e d s p e c i m e n s . R e p r o d u c e d with p e r m i s s i o n . F. Ceraurus pleurexanthemus,
appendage
structure
d r a w n by B e r g s t r o m (1972) from information d e v e l o p e d by Stormer (1939, 1951). R e p r o d u c e d with p e r m i s s i o n . G.
Cryptolithus
bellulus, a p p e n d a g e structure d e v e l o p e d by Bergstrom (1972, 1973) from pyritized s p e c i m e n s p r e p a r e d by Beecher. R e p r o d u c e d with p e r m i s s i o n . H. Phacops cf. P. ferdinandi, a p p e n d a g e structure d e v e l o p e d by B e r g s t r o m (1969) u s i n g the radiographs of pyritized s p e c i m e n s from the Hunsruck Shale in Germany. It is a s s u m e d that the p h a c o p i d trilobites of New York will have similar structures. R e p r o d u c e d w i t h permission.
the pygidium in T. eatoni is significantly m o r e than the n u m b e r
e n d o p o d . Until the work of Cisne ( 1 9 7 5 , 1 9 8 1 ) , all reconstruc-
of axial furrows on the dorsal surface of the pygidium, showing
tions of the appendages included a precoxa from which the
a weak relationship between s e g m e n t s a n d axial furrows.
e x o p o d extended ( S t o r m e r 1 9 3 9 , Figure 1, p. 155). This view is
A m o r e detailed look at an individual trilobite appendage
incorrect, based on all the material recently examined; both the
illustrates that it is a c o m p l e x structure. T h e a t t a c h m e n t to the
e x o p o d and the walking leg are attached to the s a m e apparatus,
ventral surface of the trilobite body is through a part called the
the basis. T h e e x o p o d has a series of thin, flattened filaments
basis (Figure 2 . I O C ) . ( F o r a current view on appendage n o m e n -
extending f r o m it, giving it a feather- or c o m b - l i k e appearance,
clature, see the article by RamskoTd and E d g e c o m b e ( 1 9 % ) . ) T h e
and it is carried up under the pleurae. O n l y in 7' eatoni are the
e x o p o d or outer b r a n c h is attached to the basis, which in turn is
exopods k n o w n to be long enough to extend well out from the
attached to the ventral m e m b r a n e of the trilobite. Beneath the
lateral edge of the dorsal exoskeleton. T h e large surface area of
e x o p o d , and also attached to the basis, is the walking leg, or
the small filaments led most a u t h o r s to believe that they have
LIFE-MODE
21
served for breathing, as an external gill. Bergstrom ( 1 9 6 9 ) argued
hepatopancreatic
that the filaments are t o o small to support an effective circulatory
equivalent of a liver, under the genal areas.
organs
(Figure
2.12A,
label
h),
probably
the
system, and instead they may have served as a filter of f o o d , as a
T h e gut (Figure 2 . 1 2 A , B, C, label g) passes from the stomach
means to circulate water over gill m e m b r a n e s on the ventral
through the axial region of the t h o r a x and terminates at the
surface, or possibly as a s w i m m i n g f u n c t i o n . In all the studies the
anus just under the posterior area of the pygidium (Plate 7 8 ) . T h e
exopods are drawn with the filaments lateral and posterolateral.
position of the gut is k n o w n f r o m several s p e c i m e n s of trilo-
S t o r m e r ( 1 9 3 9 ) actually f o u n d the filaments of Ceraurus pleurex-
bites because the ingested sediment often survives in place (Figure
anthemus pointed forward, but he rotated t h e m in his r e c o n -
2 . 1 2 D , label g) and has a different texture or c o l o r than the sur-
struction. Bergstrom ( 1 9 6 9 )
believed that they were pointed
r o u n d i n g stone ( R a y m o n d 1920a; Cisne 1 9 7 5 ; W h i t t i n g t o n 1993;
forward in life (Figure 2.1 I F ) . S t o r m e r ( 1 9 3 9 ) reconstructed the
Whiteley et al. 1 9 9 3 ; Brett et al. 1 9 9 9 ) . It is assumed that s o m e
filaments of the
f o r m of circulatory and nervous systems also o c c u p i e d the axial
exopod
of C.
pleurexanthemus
(Figure
2.10J),
illustrating the high surface area that supports their use as a brachial organ.
interior region. Small rodlike structures seen in radiographs (Cisne 1981) and
The endopod is multiply jointed with distinct sections called
in unusually well-preserved s p e c i m e n s ( W h i t t i n g t o n 1993) are
podomeres (Figure 2 . 1 0 E ) . T h e r e is general a g r e e m e n t that there
believed to represent muscles, and r e c o n s t r u c t i o n of the m u s c u -
are seven podomeres on all trilobites e x a m i n e d . On s o m e of the
lature related to the appendages has been proposed (Figure 2 . 1 2 A ,
podomeres, starting with the ones closest to the basis, are p r o -
B, C, label m ) . S o m e s p e c i m e n s of E. rana show s y m m e t r i c a l dark
jections, endites (Figure 2.1 OF), with hairlike setae (Figure 2 . 1 0 G )
spots on the exoskeleton ( B a b c o c k 1 9 8 2 ) . T h e s e are interpreted
near or on their tip. On
as m u s c l e a t t a c h m e n t areas.
Triarthrus, and probably most o t h e r
genera, the last p o d o m e r e is a footlike tip to the walking leg (Figure 2.101).
Two
soft-bodied
arthropods,
Naraoia
compacta
and
N.
spinifer, originally discovered from the Burgess Shale, are now
T h e most thoroughly e x a m i n e d trilobite appendages are those
regarded as trilobites and assigned to the family Naraoiidae. T h e
of T. eatoni and C. pleurexanthemus, b o t h from the Ordovician
Naraoiidae now includes five genera (Fortey and T h e r o n 1 9 9 5 ) .
of New York. T h e r e are m o r e s p e c i m e n s available of these trilo-
Two of these are O r d o v i c i a n and o n e survived to Late O r d o v i -
bites with preserved appendages than there are of any others.
cian. If, as s o m e a u t h o r s believe, the heavier exoskeleton of
Figure 2.11A is the Beecher reconstruction of T. eatoni and parts
p o s t - C a m b r i a n trilobites is an evolutionary response to m o r e
B and C of Figure 2.11 are reconstructions of C. pleurexanthemus
advanced predators, then it is unlikely that s o f t - b o d i e d trilobites
by R a y m o n d ( 1 9 2 0 a ) and S t o r m e r ( 1 9 5 1 ) . S t o r m e r ' s figure is
survived past the O r d o v i c i a n . N o n e of these genera are known
modified to show the dorsal a n a t o m y on the right and the ventral
f r o m New York, but given the special c o n d i t i o n s necessary for
on the left. Parts D and E of Figure 2.11 are r e c o n s t r u c t i o n s of
their preservation, this does not prove that they were not present.
the legs of T. eatoni by Cisne ( 1 9 8 1 ) and by W h i t t i n g t o n and A l m o n d ( 1 9 8 7 ) , respectively. Parts F, G, and H are drawings of the legs of Ceraurus,
Cryptolithus hellulus, and
Phacops cf.
P. fer-
dinandi, all as reconstructed by Bergstrom ( 1 9 6 9 ) .
Life-Mode T h e following discussion of l i f e - m o d e is based almost exclu-
Figure 2 . 1 0 K shows T. eatoni as reconstructed by W h i t t i n g t o n
sively on circumstantial evidence. As s u c h , it is highly interpre-
and A l m o n d ( 1 9 8 7 ) . T h e view is from about the midline of the
tive. Fortey ( 1 9 8 5 ) p o i n t e d out that using the s a m e body of
trilobite looking to the rear and illustrates the orientation of the
knowledge, trilobites in the family Agnostidae have been hypoth-
walking legs and their parts. T h e bases are shown with toothlike
esized to be pelagic, b e n t h i c , parasitic, a n d epifaunal, possibly
adaxial projections or gnathobases (Figure 2 . 1 0 H ) . F o o d was
attached to algal strands. T h e fossil record does not often permit
probably collected, masticated, or pulled apart, and passed along
clear, u n a m b i g u o u s c o n c l u s i o n s . However, o n e might assume
forward to the m o u t h at the posterior of the h y p o s t o m e by use
that " f o r m follows f u n c t i o n " and that a trilobite's m o r p h o l o g y is
of the e n d o p o d s and bases. Trilobites so equipped would be effec-
often a g o o d indicator of its life habits.
tive b o t t o m feeders, both as predators and as scavengers. Since
M o s t paleontologists c o n t e n d , by analogy with crustaceans,
this kind of i n f o r m a t i o n on appendages is k n o w n for so few trilo-
that for m a n y trilobites the protaspid phase was planktic. That is
bites, it is difficult to extrapolate too far as to the l i f e - m o d e of the
to say that the larvae floated and drifted in the sea, ensuring a
others.
wide dispersal of the species.
Pyritized trilobites from New York and G e r m a n y that were
Trilobites that were primarily b e n t h i c as adults probably
studied by high-definition X-ray p h o t o g r a p h y provide m u c h of
settled to the sea b o t t o m s o m e t i m e during the meraspid phase.
what we know about
1939;
Pelagic, or f r e e - s w i m m i n g trilobites, may never have left the open
Sturmer and Bergstrom 1 9 7 3 ; Cisne 1 9 7 5 , 1 9 8 1 ) . T h e i r s t o m a c h
the internal a n a t o m y ( S t o r m e r
seas during their t r a n s f o r m a t i o n to adults. All through these
(Figure 2.12A, label c ) , crop, or foregut is located in the glabella.
changes, the i m m a t u r e trilobite was very vulnerable to predators
Along with
and e n v i r o n m e n t a l stress, as the m o l t i n g process left the animal
the stomach
in
the cephalon are organs called
THE
22
FIGURE 2.12.
BIOLOGY
OF
TRILOBITES
Internal a n a t o m y of the trilobite. A. Internal o r g a n s of the c e p h a l o n of Triarthrus d e t e r m i n e d by
Cisne (1975, p. 55, Fig. 9): m, m u s c l e s ; c, c r o p or s t o m a c h ; g, gut; h, h e p a t i c o p a n c r e a t i c o r g a n . R e p r o d u c e d from Fossils a n d Strata, www.tandf.no/fossils, by J. L. Cisne, 1975, vol. 4, 4 5 - 6 3 , by permission of Taylor a n d Francis AS. B. Cross section of the thorax with the internal o r g a n s (Cisne 1975, p. 53, Fig. 7): d, dorsal vessel or "heart"; m, m u s c l e s ; g, gut. R e p r o d u c e d from Fossil a n d Strata, www.tandf.no/fossils, by J. L. Cisne, 1975, vol. 4, 4 5 - 6 3 , by p e r m i s s i o n of Taylor a n d Francis AS. C. Reconstruction of s o m e internal anatomy of Ceraurus pleurexanthemus by R a y m o n d (1920a): d, dorsal vessel or heart; g, gut; m, muscles. D. S p e c i m e n of C. pleurexanthemus that c l e a v e d to s h o w the gut (g) as a dark ferruginous stain ( M C Z 111716).
with little in the way of defense for a period of t i m e and the
(Figure 2 . 8 F ) is well d o c u m e n t e d . B o t h forms are well suited to
energy b u r d e n of continually building new exoskeletons was c o n -
their respective m o d e s of life. T h e change to a b o t t o m - d w e l l i n g
siderable. I n extant a r t h r o p o d s Clarkson ( 1 9 7 9 ) n o t e d that 8 0 %
( b e n t h i c ) f o r m c o m e s at the m e t a m o r p h o s i s f r o m protaspis to the
t o 9 0 % o f m o r t a l i t y c o m e s during the m o l t i n g process. T h e m o r e
meraspis, which is shaped like the adult but with long genal
c o m m o n trilobites had to p r o d u c e large n u m b e r s of larvae in
spines. As m e n t i o n e d earlier, the long genal spines last well into
order for significant n u m b e r s to reach maturity.
the early juvenile holaspis.
asaphid trilobite, Isotelus,
S o m e trilobite species are widely dispersed throughout the
f r o m the planktic protaspid (Figure 2 . 8 D ) to the b e n t h i c adult
world, suggesting that they were planktic or pelagic as adults and
T h e m e t a m o r p h i c c h a n g e in an
23
LIFE-MODE
FIGURE 2.13. Trilobite s h a p e s a n d functions. A. Isotelus gigas ( M C Z 311). This trilobite has a s m o o t h s h a p e suitable for shallow p l o w i n g of the surface m u d s for f e e d i n g . B. Hypodicranotus striatulus ( M C Z 100986). The streamlined s h a p e a n d the 1 8 0 - d e g r e e visual c a p a b i l i t y s u g g e s t a trilobite that m i g h t have b e e n a g o o d swimmer a n d w a s p e r h a p s pelagic. C. Achatella achates (PRI 4 9 6 5 9 ) . This trilobite has a fairly flat b o d y with eyes raised well a b o v e the rest of the c e p h a l o n . In a n a l o g y with b o t t o m dwellers with raised eyes, one might e x p e c t this trilobite to rest on the b o t t o m , with the b o d y just u n d e r the s u r f a c e of the substrate a n d the eyes a b o v e it. This position is a d e f e n s e against p r e d a t o r s a n d possibly a m e a n s of lying in wait for prey. D.
Cryptolithus bellulus (PRI 4 9 6 5 4 ) . This trilobite has a prominent, robust
c e p h a l o n c o m p a r e d to the light exoskeletal material on the thorax a n d p y g i d i u m . This feature a n d other e v i d e n c e ( C a m p b e l l 1975) s u g g e s t a sedentary lifestyle a n d filter f e e d i n g habit. E. Triarthrus eatoni (TEW collection). The a p p e n d a g e , i n c l u d i n g the exite or brachial b r a n c h , e x t e n d s well b e y o n d the e d g e of the thoracic shield. This configuration aids the trilobite to survive in the d y s o x i c , d e e p - w a t e r c o n d i t i o n s s u g g e s t e d by the dark shales in w h i c h they are f o u n d .
moved freely t h r o u g h o u t the seas. Planktic larval f o r m s would
and it is reasonable to suggest that they t o o buried themselves
also serve to disperse species but in a m o r e limited m a n n e r . D i s -
under a thin layer of sediment.
persal into new areas by the n o r m a l l y b e n t h i c trilobites is e x -
B o d y shape suggests the l i f e - m o d e of m a n y trilobites. Fortey
pected to be followed by speciation, so o n e would not expect the
( 1 9 8 5 ) defined three m o r p h o l o g i e s o f pelagic species: ( 1 ) large-
species identity to be m a i n t a i n e d if dispersal was into areas not
eyed, epipelagic, s l o w - s w i m m i n g trilobites; ( 2 ) pelagic, stream-
previously occupied by the species.
lined, faster s w i m m e r s ; and
There are wide variations in the size of trilobite eyes, the
(3)
possible s w i m m i n g Irvingella
types, remopleuridids, and progenetic types. T h e f a s t - s w i m m i n g
n u m b e r of lenses, and the angle of vision. T h e s e variations are
trilobites have r o u n d e d streamlined shapes, which p r o m o t e d
certainly s o m e indication of the l i f e - m o d e , but m o d e r n analogy
b u o y a n c y and low drag while s w i m m i n g . T h e s e shapes are not
is often necessary to c o m e up with suggestions. Animals that b u r y
often found a m o n g New York trilobites, but the Middle O r d o v i -
themselves shallowly in the b o t t o m sediment have eyes that are
cian
raised above the plane of the head, enabling t h e m to see when
and is considered pelagic (Figure 3 . 1 3 B , Plate 1 6 0 ) .
they are slightly buried. S o m e trilobites have such raised eyes (e.g., Achatella
achates
(Figure
2.13C)
and
Dalmanites
species),
remopleurid
Hypodicranotus
striatulus
has
the
right
shape
Vaulted, s m o o t h exoskeletons such as that on /. gigas (Figure 2 . 1 3 A , Plate
1 5 0 ) , Dipleura dekayi (Plate 9 7 ) , and
Trimerus del-
24
THE
BIOLOGY
OF
TRILOBITES
phinocephalus (Plate 9 9 ) were well designed to plow through the
fossils such as tracks, burrows, and distinctive pits preserved in
upper sediment layers in search of f o o d . T. eatoni, with its thin
the fossil record are attributed to trilobites, as supported by the
exoskeleton and outer b r a n c h e s that extend b e y o n d the pleurae,
rare find of a trilobite at the end of a trackway or in o n e of the
was unsuited for shallow, t u r b u l e n t water and for plowing in sed-
burrows (Figure 2 . 1 4 A ) . Two c o m m o n t r a c e s — C r u z i a n a and
i m e n t and was better designed for surface scavenging in deeper,
Rusophycus—are generally preserved as molds
less oxygenated e n v i r o n m e n t s (Figure 2 . 1 3 E , Plate 1 7 2 ) .
basal c o n t a c t of sandstones or c a r b o n a t e beds in shales. O n e type
It has been proposed that to m a x i m i z e visual effectiveness,
(fillings)
on the
of deep, inscribed, horizontal track or furrow, Cruziana, shows
the plane of the upper and lower edges of the eyes should be
" V - l i k e " scratch patterns m a d e by the dactyls (claws) of the trilo-
parallel to the substrate (Plates 5 a n d 6 ) . In m a n y outstretched
bite and a central groove corresponding to an axial ridge of debris
trilobites it is apparent that the eyes are parallel to the s u b -
pushed up by the trilobite (Figure 2 . 1 4 B ) . T h e bilobed burrows,
strate. However, m a n y species of illaenids, when outstretched,
or resting pits also showing V-shaped scratches, are called Ruso-
have eyes that are angled upward and posteriorly. Westrop
phycus, and the trackways consisting of small " f o o t p r i n t s " on the
( 1 9 8 3 ) and B e r g s t r o m ( 1 9 7 3 ) , a m o n g others, argued that these
substrate
trilobites were i n f a u n a l , b u r y i n g themselves backward into a
1 9 9 0 , p. 1 6 1 ) , although O s g o o d ( 1 9 7 0 ) did not hold this t e r m in
soft b o t t o m with their cephalon on the surface at an angle to the
high regard.
thoracopygidium.
are
sometimes
known
as
Diplichnites
(see
Bromley
Trace fossils attributed to various burrowing animals (worms?)
In this attitude the eye base is parallel to the surface and gives
have been f o u n d ending in Rusophycus, suggesting the trilobite
the m a x i m u m all-around vision. T h e s e infaunal trilobites fed and
had attacked a n o t h e r burrower. T h e s e fossils indicate that m a n y
breathed by the exchange of water on the buried ventral anatomy.
trilobites walked a r o u n d on the b o t t o m and dug into the sediment
T h i s exchange o f water was the result o f the m o v e m e n t o f the
for b o t h food and resting places (Hall 1852, Plate 9, Figure 1).
appendages a n d a n upstream o r i e n t a t i o n o f the burrow. T h e r e
In the case of Cruziana the direction of travel for the trilobite
are other trilobites with this l i f e - m o d e , which Westrop termed
is toward the o p e n end of the V-shaped appendage traces. M o s t
" i l l a e n i m o r p h s . " W h i t t i n g t o n ( 1 9 9 7 b ) rebutted this view on the
Rusophycus traces f o r m a V, with the gape end or anterior being
basis of the high flexibility of the t h o r a x in illaenids and that they
wider than the posterior, suggesting that the trilobite rested (or
are m o r e suited to crawling a r o u n d the b o t t o m and over irregu-
h u n t e d ) with the cephalon toward the " g a p e " end. T h e r e is little
lar objects than living or resting primarily in burrows.
a r g u m e n t that Rusophycus traces are most readily explained as
Westrop also p o i n t e d out that on s o m e of the illaenimorphs
trilobite h u n t i n g or resting pits, but the same is not true for
there is a median tubercle on the glabella, midway between the
Cruziana. W h i t t i n g t o n ( 1 9 8 0 ) , based on his in-depth studies of
palpebral lobes on the sagittal line. T h i s tubercle is also a thin
Olenoides
spot and is characterized as having possible light-sensing p r o p -
readily allow for the type of traces represented by Cruziana and
erties. It is the highest point when the b o d y is in a n o r m a l life
that s o m e o t h e r a n i m a l , perhaps not even an a r t h r o p o d , may be
serratus,
believed
that
trilobite
appendages
do
not
position, thus covering any blind spots of the c o n v e n t i o n a l eyes.
responsible. However, m a n y Cruziana traces end in Rusophycus,
R u e d e m a n n ( 1 9 1 6 b ) f o u n d a significant n u m b e r trilobites with
and since the latter are u n a m b i g u o u s l y trilobite, this reference is
such median tubercles, even n o m i n a l l y blind trilobites such as in
questionable.
the genus Cryptolitluis.
It is reasonable to c o n j e c t u r e that the
In New York, traces attributed to trilobites are c o m m o n in the
tubercles had a light-sensing utility and played a role in the trilo-
Silurian C l i n t o n G r o u p , particularly on the base of sandstone
bite's life-mode. Such light sensing tubercles probably could sense
layers near the village of C l i n t o n , Oneida County. O s g o o d and
m o v e m e n t but not resolve o b j e c t s . In m o d e r n a r t h r o p o d s larger eyes are f o u n d on n o c t u r n a l
D r e n n e n ( 1 9 7 5 ) provided a g o o d description of these traces and their literature. In o t h e r strata they are far less well k n o w n , either
species or those adapted to low daylight levels. A n i m a l s with a
because c o n d i t i o n s were n o t right for their preservation
wide visual angle need it to watch for predators. Very large eyes
because little effort has been m a d e to find and identify t h e m in
and a wide visual angle are seen on s o m e pelagic trilobites (Figure
appropriate strata.
2 . 1 3 B ) . Fortey ( 1 9 8 5 ) considered the large-eyed trilobites as epipelagic and slow s w i m m e r s . C o m p o u n d eyes permit insects to be highly aware of m o v e -
or
Fortey and O w e n ( 1 9 9 9 ) proposed that trilobite feeding habits can be related to the position and a t t a c h m e n t of the h y p o s t o m e and other physical characteristics. Trilobites that are considered
m e n t but do not necessarily provide high visual acuity. R e d u c -
predatory (i.e., they fed o f f m a c r o f a u n a such as w o r m s ) had
tion in eye size has been noted for trilobite genera that m o v e d to
a c o n t e r m i n e n t h y p o s t o m e fixed or strongly supported at the
deeper water through t i m e . Blind trilobites, such as in the genus
anteroventral c e p h a l o n . T h e h y p o s t o m e provided a strong base
Cryptolithus (Figure 2 . 1 3 D ) , may have b u r r o w e d into sediment
for the appendages so the trilobite could manipulate and masti-
where sight would have been less i m p o r t a n t than o t h e r sensory
cate the prey. F o o d was passed forward along the ventral median
capabilities.
by the bases to the m o u t h at the posterior of the hypostome.
M o s t trilobites were b e n t h i c . T h e y passed m o s t of their life
Examples of this type of h y p o s t o m e a t t a c h m e n t in an Isotelus
on or in the u p p e r m o s t part of the sediment layer. S o m e t r a c e
species may be seen in Figure 2 . 7 E and Plates 153, 155, and 157.
25
LIFE-MODE
FIGURE 2 . 1 4 .
Trilobite traces. A. Rusophycus pudicum ( U C M 3 7 5 7 4 ) . S a n d s t o n e d e p o s i t s over trilo-
bite-rich b o t t o m m u d s often have c o n v e x , slightly V - s h a p e d traces on their lower s u r f a c e . These t r a c e s are known as Rusophycus a n d have b e e n long r e g a r d e d as trilobite "resting t r a c e s . " O s g o o d ( 1 9 7 0 ) reported on a remarkable Rusophycus that h a d the trilobite responsible for it still in p l a c e . B. Flexicalymene meeki. This trilobite w a s f o u n d on the Rusophycus in A. The trilobite is a b o u t 46 mm long a n d is from the U p p e r O r d o v i c i a n of Ohio. C. Trachomatichnus numerosum ( U C M 3 7 6 9 5 ) . A trilobite w a l k i n g trace attributed to Cryptolithus ( O s g o o d 1 9 7 0 ) . The illustration is life size. All figures r e p r o d u c e d with permission.
Impendent hypostoma that are also attached to the d o u b l u r e also
(weak)
suggest a predatory habit. Bellacartwrightia species (Plate 4 7 ) and
c e p h a l o n , as well as trace fossils clearly attributable to Cryp-
Calyptaulax callicephalus
tolithus resting ( a n d feeding) sites.
(Plate
117)
show this
mode
of h y p o -
stome a t t a c h m e n t .
thorax
and
thoracic
appendages
compared
to
the
Trilobites are f o u n d in a variety of e n v i r o n m e n t s , from fairly
Trilobites whose h y p o s t o m a were not strongly attached to the
shallow waters near s h o r e , to reefs, c o n t i n e n t a l shelves and slopes,
cephalon (i.e., natent) are considered to be particle feeders. T h e y
and m o d e r a t e l y deep basins. T h e observation has been m a d e
relied on m u c h smaller food particles swept up f r o m the b o t t o m ,
that trilobites from the shallower areas with m o r e wave turbul-
and the rigid h y p o s t o m e was unnecessary. T h e s e trilobites tend
ence have thicker exoskeletons (Fortey and W i l m o t 1 9 9 1 ) . T h e s e
to be smaller than the predatory ones because their food sources
thicker exoskeletons are possibly an evolutionary response to the
were not as rich and c o n c e n t r a t e d . T h e genera Harpidella (Plate
greater e n v i r o n m e n t a l energy. As m e n t i o n e d earlier, exoskeletons
128) and Triarthrus (Plates 170 to 174) represent this group of
are generally thicker in p o s t - C a m b r i a n trilobites, which may also
trilobites. The
last
signal the rise of better-developed predation, a n o t h e r form of feeding m o d e to
consider here
is filter-chamber
e n v i r o n m e n t a l stress.
feeding. This type of feeding is typical of trilobites with reduced
M a n y trilobites were gregarious, at least at s o m e point during
mobility and relatively large cephala. T h e s e trilobites settled in a
their life cycles. T h e large n u m b e r s of death and molt assem-
position and stirred up the sediment immediately under t h e m ,
blages, well illustrated by E. rana in New York, are no statistical
and then filtered out the m i n u t e food particles c o n t a i n e d in the
accidents. It is not u n c o m m o n , within a n u m b e r of different
top layer of sediment. M o v e m e n t o c c u r r e d only after the food
trilobite species, for a large n u m b e r of individuals to be found in
supply was exhausted. T h e genus Cryptolithus (Plates 163 to 167)
local " p o c k e t s " on the s a m e bedding plane or horizon, indicating
is the example used, and the evidence is the relatively small
s o m e f o r m o f group behavior (Plates 5 9 , 8 9 , 102, 128, 146, 147,
26
THE
BIOLOGY
OF
TRILOBITES
and 1 5 2 ) . All this suggests that it was c o m m o n for m a n y trilo-
d a m a g e . T h e s e m a l f o r m a t i o n s can c o m e about in several ways,
bites to congregate for breeding or m o l t i n g , or just because it was
but d a m a g e due to p r o b l e m s in molting and damage caused by
their n o r m a l l i f e - m o d e to be together in " s c h o o l s " (Speyer and
actual attack by a predator were probably the most c o m m o n . T h e
Brett 1985, Speyer 1 9 9 0 a ) .
m e c h a n i s m of a defect is not always clear, but healed punctures
Trilobites such as phacopids and calymenids were capable
and crescent-shaped m a l f o r m a t i o n s are readily attributed to pre-
of very tight e n r o l l m e n t , literally into a ball. T h i s position was
dation. Figure 2 . 1 5 illustrates four examples of exoskeletons with
undoubtedly a defense m e c h a n i s m resorted to in times of stress.
clear indication of predation. Panels A and B show " b i t e " marks
If the stress was an undersea s e d i m e n t flow t o o large to get out
out of trilobites from the Rochester Shale that have been through
of, the trilobite would be e n t o m b e d in the tightly enrolled posi-
at least o n e m o l t , as shown by the broken edges of the thoracic
tion. Most of the p o s t - C a m b r i a n trilobites in New York could
s e g m e n t s being r o u n d e d to a new termination. Panel C shows the
enroll, and the frequency of this position versus the o p e n posi-
unusual situation of Dalmanites limulurus with the pygidial spine
tion is perhaps an indication that it was a c o m m o n reaction to
missing ( c o m p a r e to Figure 2 . 1 5 A ) and the damage healed over.
stress for the species.
Panels D through F show a calymenid from the Rochester Shale
S o m e b e n t h i c trilobites u n d o u b t e d l y could swim. M o d e r n
with evidence of b o r i n g on its exoskeleton. This finding is par-
horseshoe c r a b s , a n o r m a l l y b e n t h i c species, are g o o d s w i m m e r s .
ticularly interesting because crinoids from the Rochester Shale
T h e y also swim upside d o w n , and it has been shown that the
have been described with similar boring marks (Brett
hydrodynamics of their s w i m m i n g works best in this attitude
1 9 8 5 ) . S i g n o r and Brett ( 1 9 8 4 ) and Pratt ( 1 9 9 8 ) s u m m a r i z e d the
(Fisher 1 9 7 5 ) . It is reasonable to a s s u m e that s o m e n o r m a l l y
possible
benthic trilobites could swim also and possibly quite well. S o m e
d o c u m e n t e d predator o f the C a m b r i a n , and many o f the circular
predators
in
the
Paleozoic.
Anomalocaris
is
a
1978, well-
likely swam upside d o w n . ( H . B u r m e i s t e r first proposed this
scars on trilobites are attributed to the circular m o u t h of Anom-
in 1843.) T h i s m o d e of s w i m m i n g may not have been involved in
alocaris. C e p h a l o p o d s b e c a m e a predation factor in the O r d o v i -
their
cian, and fishes b e c a m e p r o m i n e n t in the Devonian.
food
gathering,
but
they
could
move
from
place
to
place and evade danger by s w i m m i n g . In o n e trilobite bed, the
Babcock
(1993)
has collected
information
related to the
result of a burial event, at least 9 8 % of the trilobites with a wide
c o n c e p t of behavioral a s y m m e t r y . T h i s means that when a trilo-
variety of sizes are f o u n d buried upside down ( W h i t e l e y et al.
bite was attacked by a predator, its response was not r a n d o m ,
1993; Brett et al. 1 9 9 9 ) . T h i s observation applies to b o t h the lower
b u t there was a preference to m o v e in a m a n n e r that resulted in
surface and internal to the l i m e s t o n e . For m o r e on this, see
m o s t d a m a g e to the right side of the animal. Conversely, pre-
Chapter 3.
ferred d a m a g e to the right side of the trilobite could suggest the
Spininess in trilobites has invoked a n u m b e r of explanations,
attack strategy of the predator.
most o f t h e m probably correct for o n e species o r another. T h e r e
G e n e t i c or embryological abnormalities cannot be easily diag-
seems to be little need to invoke j u s t a single e x p l a n a t i o n , any
nosed in fossils. Pathological abnormalities are due to disease and
m o r e than there is o n e explanation for spininess in m o d e r n
parasites. Disease is impossible to d o c u m e n t in fossils, but para-
species of a r t h r o p o d s . Spines can be a defense m e c h a n i s m against
sitic attack is seen by the presence of w o r m - s h a p e d borings and
predators, provide support on a soft substrate, assist the a n i m a l
gall-like swellings. It is m o r e difficult to determine if borings were
in burying itself when
The
m a d e on the living animal (versus on the exuviae or p o s t m o r t e m )
Lower Devonian s t r a t u m in New York ( a n d the Devonian strata
than to recognize a healed injury. Swellings are known from a
necessary, and sensory devices.
of O k l a h o m a and M o r o c c o ) has trilobites with elaborate spines,
n u m b e r of different trilobite families, and s o m e can be diagnosed
s o m e curling up and over their t h o r a x . T h e s e spines of the genus
as the result of parasites based on the direct presence of w o r m -
Dicranurus c o m m o n l y carried algae and o t h e r encrusting org-
like structures.
anisms on t h e m , possibly as a defense m e c h a n i s m ( K l o c 1 9 9 3 ,
M c N a m a r a and Rudkin ( 1 9 8 4 ) d o c u m e n t e d the death of a
1 9 9 7 ) . T h e spines provided g o o d a t t a c h m e n t s and presumably
partially molted Pseudogygites latimarginatus.
helped break up the visual b o d y lines to provide c a m o u f l a g e .
the a n i m a l was o v e r c o m e and buried while molting.
S o m e m o d e r n a r t h r o p o d s do exactly this.
It seems likely that
Often trilobites are f o u n d in association with other fossils in
O n e can a s s u m e , based on m o d e r n analogy, that trilobites
rapid-burial deposits. If there is little indication of their being
were subject to injury, parasitism, and predation, as reflected in
t r a n s p o r t e d any distance, then this can be taken as evidence of
their preserved parts. O w e n ( 1 9 8 5 ) extensively reviewed trilobite
their ecology. An example is the o d o n t o p l e u r i d Meadowtownella
abnormalities.
He listed three general types of trilobite a b -
trentonensis from the Trenton G r o u p . T h i s small, spiny trilobite
n o r m a l i t i e s : injury, genetic or embryological m a l f u n c t i o n , a n d
is often f o u n d whole on fossil hash layers, particularly with
pathological a b n o r m a l i t i e s .
b r a n c h e d bryozoans, and also in burial event deposits with the
Not u n c o m m o n l y , trilobites are f o u n d with m a l f o r m a t i o n s
cystoid
Cheirocrinus
and
fenestrate
bryozoans.
M.
trentonensis
that are ascribed to healed injuries (Figure 2 . 9 B ) . M o s t of these
was probably a scavenger on b o t t o m s with animal debris accu-
injuries are seen on the pleura either by a s y m m e t r y or by healed
m u l a t i o n s and also in bryozoan thickets with their attached
FIGURE 2.15.
Trilobite injuries. A. Dalmanites limulurus with a semicircular portion of the
thorax missing. The d a m a g e has " h e a l e d " in that the e d g e s of the d a m a g e are r o u n d e d , indicating the trilobite has molted at least o n c e s i n c e the injury (K. Smith collection). B. Dicranopeltis nereus with an injury to the thorax. The trilobite has m o l t e d at least o n c e since the injury (K.
Smith collection).
C.
Dalmanites limulurus with the p y g i d i a l spine
missing. The e n d of the p y g i d i u m is r o u n d e d , indicating one molt s i n c e the loss of the spine. (K. Smith collection). D-F. Calymene s p e c i e s , s h o w i n g circular " b o r i n g s " (arrows) similar to those of Tremichnus on several different s p e c i e s of c r i n o i d s from the Rochester Shale reported by Brett (1985) (NYSM 16796).
THE
28
FIGURE 2.16.
BIOLOGY
OF
TRILOBITES
Cryptolithus, the
m o s t - s t u d i e d trilobite g e n u s f o u n d in New York. A. Cryptolithus tessellatus (TEW
collection,
whitened). This trilobite, in N e w York, is f o u n d only in the M i d d l e Ordovician Sugar River Formation. It is r e c o g n i z e d by the three rows of pits anterior to the c h e e k area (arrow).
B.
Cryptolithus
lorettensis
(PRI 49657, w h i t e n e d ) . In New York this trilobite is f o u n d only in the upper Sugar River Formation. It differs from C. tessellatus in that there are four rows of pits anterior to the c h e e k (arrow). The first approximately nine radial abaxial pit rows are well a l i g n e d . C. Cryptolithus
bellulus (PRI
49654,
latex pull, w h i t e n e d ) from the U p p e r O r d o v i c i a n Lorraine G r o u p in New York. This trilobite differs from C. lorettensis primarily in the poor radial alignment of the first four abaxial pit rows. D. A d r a w i n g of a silicified s p e c i m e n of C.
tessellatus by C a m p b e l l
(1975). R e p r o d u c e d with permission. E. A d r a w i n g of the same s p e c i m e n by B e r g s t r o m (1972) with the a p p e n d a g e s drawn in. The a p p e n d a g e information is from B e e c h e r s p e c i m e n s of C. bellulus. R e p r o d u c e d with p e r m i s s i o n . F. Raymond's (1920a) reconstruction of the ventral anatomy of C. bellulus using
specimens
p r e p a r e d by Beecher. G. Bergstrom's (1972) reconstruction of the s a m e s p e c i m e n s . R e p r o d u c e d with permission.
cystoids. A further possibility is that this trilobite fed o f f living
preserved in a wide variety of e n v i r o n m e n t s and the possibility
bryozoa.
of new i n f o r m a t i o n on the lifestyle and biology is enhanced.
Trilobites of the genus Cryptolithus are a m o n g the best u n d e r -
Cryptolithus
specimens
with
appendages
are
preserved
in
stood of the New York trilobite genera (Figure 2 . 1 6 ) . T h e r e are
Beecher's Trilobite B e d , which enables detailed observations of
several reasons for this. T h e genus is widely distributed g e o -
the ventral a n a t o m y ( B e e c h e r 1895a, R a y m o n d 1920a (Figure
graphically and geologically. W i d e distribution m e a n s that it is
2.16F), Bergstrom
1972 (Figure 2 . 1 6 G ) ) . At least o n e whole,
29
LIFE-MODE three-dimensional s p e c i m e n , preserved in silica, is k n o w n . Figure
covered by W h i t t i n g t o n ( 1 9 5 9 ) . P h o t o g r a p h s of this specimen
2 . 1 6 D is a drawing of the specimen by C a m p b e l l ( 1 9 7 5 ) , and
reproduced by C a m p b e l l ( 1 9 7 5 ) reveal that the ventral plane of
Figure 2 . 1 6 E is a drawing of the same s p e c i m e n by B e r g s t r o m
the t h o r a c o p y g i d i u m was well above the apparent plane of the
with the legs included. Walking and digging trace fossils unequiv-
ventral surface of the c e p h a l o n . In o r d e r to m o v e about on the
ocally assigned to Cryptolithus are k n o w n f r o m Kentucky. T h e
b o t t o m and to burrow, the trilobite must have had long, strong,
Cryptolithus protaspid is s o m e t i m e s found silicified and is easily
ventral walking legs or have developed o t h e r m o d e s of m o v e -
characterized. T h e unique c e p h a l o n with its heavily pitted b r i m
m e n t . C a m p b e l l ( 1 9 7 5 ) explored this in detail, but in s u m m a r y
is readily recognized in stratigraphic samples, and it is impossi-
Cryptolithus species could n o t have been
ble to mistake it for other genera. A n u m b e r of authors have
or deep burrowers (see Figure 2 . 1 6 G ) . O s g o o d ( 1 9 7 0 , Plate 5 8 ,
very active crawlers
studied the distribution of Cryptolithus so there is a large data-
Figure 1 and 2) figured the resting trace fossil Rusophycus cryptolithi, which because of size and the impressions of genal spines
base of i n f o r m a t i o n . In New York there are three distinct species or " m o r p h s " of
could only have been m a d e by Cryptolithus a n i m a l s . T h e s e traces
Cryptolithus ( W h i t t i n g t o n 1 9 6 8 , Shaw and Lesperance 1 9 9 4 ) : C.
indicate that the trilobite sat in a shallow depression, facing into
tessellatus (Figure 2 . 1 6 A ) , C. lorettensis (Figure 2 . 1 6 B ) , b o t h from
the c u r r e n t , and swept particles of detritus f r o m the b o t t o m into
the Middle Ordovician Sugar River F o r m a t i o n , and C. bellulus
its m o u t h .
(Figure 2 . 1 6 C ) from the Upper Ordovician Lorraine G r o u p , all in
T h e m o u t h of Cryptolithus species is at the rear of the small
New York. T h e y are distinguished primarily by the rows of pits
h y p o s t o m e in the ventral part of the c e p h a l o n . T h e s t o m a c h
or the pit a r r a n g e m e n t , or b o t h , so that it is justified to assume
occupies the glabella, a n d digestive capability extends out into the
that any biological i n f o r m a t i o n from o n e species is essentially the
genal area. T h e a l i m e n t a r y track lay along the axis of the t h o r a -
same for all of t h e m .
c o p y g i d i u m and o c c u p i e d a b o u t 2 0 % o f the width o f the axial
Trinucleids arose as a family in Europe and migrated to North America during the Middle O r d o v i c i a n
(Whittington
rings. T h e anus is at the posterior p o i n t of the pygidium. Fortey and O w e n s
(1999)
described
Cryptolithus species as
1 9 6 8 ) . T h e pelagic protaspis ( C h a t t e r t o n et al. 1994) ensured that
filter-chamber feeders, m e a n i n g that the resting trilobites stirred
o n c e in the North A m e r i c a n epicontinental sea, the trilobite
the sediment directly u n d e r t h e m , using the cavity between the
spread rapidly wherever currents t o o k the protaspis. Molts f r o m
cephalon and the substrate, and filtered o u t the food particles
protaspides and cephala of what is probably the meraspid phase
from the rest of the suspended s e d i m e n t . Fortey and O w e n s also
are c o m m o n l y found in the deep-water Frankfort Shales includ-
suggested that the cephalic perforations provided c h a n n e l s for
ing the Beecher's Trilobite Beds. T h e holaspid is blind except
water to flow out of this cavity while it was swept forward by the
for the possible eye spot or visual receptor centered on the
appendages. T h i s flow b r o u g h t the food particles forward to the
median line of the glabella. T h e r e is a wide b r i m on all but the
m o u t h and kept oxygenated water flowing over the exopods.
posterior of the cephalon. T h i s b r i m is bilaminar, separating into
As
in
all
specimens
of trilobites
with
preserved ventral
an upper and lower lamella through a plane parallel to the ventral
appendages, the b i r a m o u s limbs of Cryptolithus included walking
plane of the trilobite. T h e b r i m is perforated with holes, c o m -
legs, e n d o p o d s , and o u t e r b r a n c h e s , e x o p o d s , which may have
monly referred to as pits, that pass through b o t h lamellae. T h e
served as a breathing organ as well as provided s o m e ability to
pits are in circumradially arranged rows for the first three or four
sweep the surface under the trilobite. T h e exopods do not extend
circumferal rows. T h e r e are a n u m b e r of speculations as to the
b e y o n d the b o r d e r of the t h o r a c i c s e g m e n t s . T h e r e are three pairs
function of the pits. T h e m o s t current thinking is that they
of appendages under the c e p h a l o n and o n e pair under each
were sensory devices, perhaps to d e t e r m i n e c u r r e n t direction
t h o r a c i c segment. U n d e r the pygidium there are a large n u m b e r
(Campbell 1 9 7 5 ) .
o f m u c h - r e d u c e d appendages, reflecting the n u m b e r o f fused
T h e long genal spines are on the lower lamella. Cephala are
segments in the pygidium.
found with and without genal spines, as are n e a r - w h o l e a r t i c u -
A s s u m i n g the relationship of the appendages to the exoskele-
lated specimens. T h e trilobite molted by m o v i n g forward through
ton is correct, it is hard to see m e m b e r s of the genus Cryptolithus
a gap between the lamella, and this gap possibly closed after
as active surface crawlers.
molting (a m e c h a n i s m observed in extant h o r s e s h o e c r a b s ) .
On the w h o l e , o n e can a s s u m e that trilobites initially occupied
Alternatively, the lower lamella b e c a m e detached during the
m a n y of the e n v i r o n m e n t a l niches that are o c c u p i e d today by
molting process. Consequently, it is difficult to k n o w if a c o m -
m o d e r n m a r i n e a r t h r o p o d s . T h e ecological niche for the indi-
pletely whole articulated specimen with the genal spines intact is
vidual species enabled trilobites to b e c o m e part of a p a l e o c o m -
a molt or an animal killed and buried. T h e absence of genal spines
munity. W i t h i n this c o m m u n i t y the trilobites shared the local
and lower lamella, however, ensures it is a m o l t .
e n v i r o n m e n t with a variety of o t h e r a n i m a l s and plant life. W h e r -
T h e thorax and pygidium are m u c h reduced c o m p a r e d to the
ever o n e finds the necessary associations within the rocks, o n e can
cephalon. T h e r e are six t h o r a c i c segments and a small triangular
expect
pygidium. A nearly whole silicified Cryptolithus species was dis-
is no different than what is seen in extant, and undisturbed,
t o f i n d the o t h e r
m e m b e r s o f the c o m m u n i t y . T h i s
30
THE
BIOLOGY
OF
TRILOBITES
c o m m u n i t i e s today. S o m e trilobites, such as the illaenids, are
tion must offer a competitive advantage to the species. N o n c o m -
f o u n d in a fairly n a r r o w range of e n v i r o n m e n t a l c o n d i t i o n s ,
petitive genetic changes will s o o n disappear, as the animal is
and s o m e like in the genus Isotelus are f o u n d in a wide variety
unable to c o m p e t e for the o p p o r t u n i t y to pass the changes along
of c o m m u n i t i e s from shallow nearshore areas to deep r a m p -
to its offspring. Next, the new trait should o c c u r in an isolated
basin transition areas. Fortey ( 1 9 7 5 ) defined c o m m u n i t i e s in the
small p o p u l a t i o n so that it will not be " l o s t " in a m u c h , m u c h
northern
c o m m u n i t i e s , the
larger gene pool. Since m u t a t i o n occurs relatively frequently, a
cheirurid-illaenid and the olenid, fit m u c h of the New York
beneficial m u t a t i o n will happen at s o m e w h a t regular intervals,
Middle Ordovician very well.
statistically. In a stable e n v i r o n m e n t , however, with many others
Europe
Ordovician.
Two
o f his
T h e geographic restrictions of specific trilobite families and
of the same species, this change may not b e c o m e fixed. A better
genera also are used to identify p a l e o b i o g e o g r a p h i c provinces.
o p p o r t u n i t y for a new m u t a t i o n to be passed along is when a
W h i t t i n g t o n ( 1 9 6 1 b ) , W h i t t i n g t o n and Hughes ( 1 9 7 2 ) , and Ross
group, for s o m e reason, is o c c u p y i n g an e n v i r o n m e n t where there
( 1 9 7 5 ) , for e x a m p l e , used this a p p r o a c h to define the early posi-
is little o u t b r e e d i n g c o m p e t i t i o n or there are new environmental niches to occupy. Essentially populations are stable until a change
tions o f the p a l e o c o n t i n e n t s . T h e early evolutionary success of trilobites was probably due
takes place in an isolated e n v i r o n m e n t , and after this c h a n g e (or
to their development of a mineralized exoskeleton and their wide
c h a n g e s ) , the new species b e c o m e s competitive with the f o r m e r
geographic dispersal. T h e n u m b e r o f trilobite genera increased
stable species and displaces it or in s o m e cases occupies a differ-
from their first a p p e a r a n c e until the Late C a m b r i a n and then
ent available niche. T h u s , evolution is not a process of continual
decreased c o n t i n u o u s l y through the Paleozoic. T h i s is graphically
small changes b u t o n e of relative stability followed by abrupt step
shown in Ludvigsen ( 1 9 7 9 b , Figure 9 ) . A n u m b e r of explanations
changes. Eldredge and G o u l d ( 1 9 7 2 ) used the term punctuated
for this have been proposed. T h e n u m b e r of potential predators
equilibria to reflect their observation that evolution is not a
continually increased d u r i n g these s a m e times. It is likely that
s m o o t h transition f r o m o n e species to the other b u t rather is
the increased predation, increased n u m b e r o f c o m p e t i t o r s for
c o m p o s e d of periods of relative stability punctuated by periods
environmental niches, and the b u r d e n of m o l t i n g to a completely
o f rapid c h a n g e .
defenseless individual all played a part in the reduced success of
T h e observation
that s o m e
fossil
c o m m u n i t i e s s h o w re-
trilobites through t i m e . Trilobites disappeared completely at the
m a r k a b l e stability, s o m e t i m e s over millions of years, has led
end o f the P e r m i a n .
to s o m e i n - d e p t h investigations. In New York s o m e Middle Devonian fossil c o m m u n i t i e s , particularly in dysaerobic envir o n m e n t s , show this stability. As a result of these and o t h e r
Evolution and Cladistics
studies, Brett and Baird ( 1 9 9 2 , 1 9 9 5 ) coined the term coordinated
Fortey and O w e n s ( 1 9 9 7 ) reviewed the evolutionary history of
stasis for this f o r m of evolutionary stability (see also K a m m e r
trilobites. T h i s review should be considered the latest in what will
et al. 1 9 8 6 , M o r r i s et al. 1 9 9 5 , Brett et al. 1 9 9 6 ) . Similarly in
be an o n g o i n g series of a r g u m e n t s .
the C a m b r i a n , for e x a m p l e , there is evidence that populations
T h e phylogeny or evolution of trilobites is k n o w n f r o m the
of trilobites in the shallower water environments underwent a
first calcified r e m a i n s in the Lower C a m b r i a n rocks to the last
n u m b e r of e x t i n c t i o n s , and the area where they o n c e were was
trilobites in the Late P e r m i a n . It is generally believed that trilo-
repopulated with trilobites f r o m deeper water. T h e s e episodic
bites as a class are m o n o p h y l e t i c ; that is they are f r o m a c o m m o n
e x t i n c t i o n s and repopulations, called biomeres ( P a l m e r 1 9 6 5 ,
ancestor ( R a m s k o l d and E d g e c o m b e 1 9 9 1 ) . T h e earliest k n o w n
1 9 8 4 ) , are recorded from the C a m b r i a n of North A m e r i c a (see
trilobites are from the s u b o r d e r Olenellina f o u n d exclusively in
also E d g e c o m b 1 9 9 2 ) .
the Lower C a m b r i a n . T h e s e trilobites lack facial sutures, which is
Relationships of trilobites at all t a x o n o m i c levels are currently
considered a primitive characteristic (Fortey and W h i t t i n g t o n
being revised using cladistic methodology. Cladistics as used in
m e m b e r of
paleontology is the grouping of taxa by their shared physical c h a r -
this early group. Facial sutures first appear in the s u b o r d e r
acteristics. Close relationships are based on synapomorphies or
Redlichiina, also in the Lower C a m b r i a n . It is p r o b a b l e that there
"shared derived" characteristics. Traits may be divided into p r i m -
1989).
In
New York
Elliptocephala
asaphoides
is
a
are ancestral trilobites that did not have mineralized exoskeletons,
itive ( p l e s i o m o r p h i c ) or derived ( a p o m o r p h i c ) . For trilobites the
perhaps back into the late P r e c a m b r i a n . T h e r e is no c o m p e l l i n g
b i r a m o u s appendages are plesiomorphic or "shared primitive"
reason to believe that all trilobites sprang from olenellin a n c e s -
characteristics, m e a n i n g they are primitive to the group (i.e., they
tral stock.
represent a c o m m o n ancestral trait of a r t h r o p o d s not exclusive
F r o m these ancestors evolved the large n u m b e r of trilobite
to trilobites) and may be used only to c o m p a r e trilobites with
orders, families, and genera that are recognized today. Evolution,
o t h e r a r t h r o p o d s . Schizochroal eyes are only f o u n d in the subor-
however, is not s o m e t h i n g that proceeds s m o o t h l y with a calen-
der P h a c o p i n a , and thus this characteristic forms a derived char-
dar-like precision. For evolutionary c h a n g e to occur, at least two
acteristic or a p o m o r p h y . A n o t h e r example involves the trilobite
m a j o r factors must be in place. First, any genetic c h a n g e or m u t a -
h y p o s t o m e . Fortey ( 1 9 9 0 a ) developed the a r g u m e n t that hypos-
EVOLUTION
AND
CLADISTICS
31
t o m e a t t a c h m e n t , natent versus c o n t e r m i n a n t versus i m p e n d -
trilobites by the t i m i n g of the a p p e a r a n c e of the selected derived
ent, is an
characteristics. W i t h a large n u m b e r of characteristics, the g r o u p -
indicator of trilobite phylogeny.
other relationships, Fortey ( 1 9 9 0 a , Figure phylogeny/hypostome
attachment
chart
for
Using these a n d 19)
constructed a
trilobites,
ings are best d o n e with c o m p u t e r p r o g r a m s designed for cladis-
which
tics that search for the closest or most p a r s i m o n i o u s fit. Cladistics
By selecting a significant n u m b e r of derived characteristics
depth review, see the works by Fortey ( 1 9 9 0 b , 2 0 0 1 ) and Novacek
summarizes the current state of knowledge. and evaluating their presence or absence, o n e can group related
is clarifying m a n y relationships a m o n g trilobites. For a m o r e inand W h e e l e r ( 1 9 9 2 ) .
3
Taphonomy
Taphonomy is t h e study of processes that influence the preser-
a c c r e t i o n , the fossil is evidence of the death of an individual. C o n -
vation of potential fossils. T h i s field e n c o m p a s s e s the disciplines
versely, with trilobites, the presence of body parts is not a simple
of
indicator o f population density.
biostratinomy,
the
study
of
processes
affecting
organism
remains or traces prior to their final burial, and fossil diagenesis, the investigation of p h e n o m e n a affecting potential fossils after burial. Recently, t a p h o n o m y has developed b o t h as a m e a n s of assessing bias in the fossil record and m o r e positively, as a critical tool for p a l e o e n v i r o n m e n t a l analysis. T a p h o n o m i c analyses
Death, Decay, and Disarticulation Death
and fossil g e o c h e m i s t r y provide valuable i n f o r m a t i o n on the
T h e t a p h o n o m i c history o f most organisms generally begins
physical and chemical p a r a m e t e r s o f e n v i r o n m e n t s . T h e a s s u m p -
with their death, although in a r t h r o p o d s , including trilobites,
tions of u n i f o r m i t a r i a n i s m are applicable at this level because the
molted exuviae also b e c o m e a part of the preserved record. Death
physical and c h e m i c a l properties o f the skeletons o f o r g a n i s m s
of o r g a n i s m s m a y involve gradual n o r m a l mortality. However,
have probably been invariant t h r o u g h geologic t i m e , despite the
m a n y of the spectacular Lagerstatten occurrences involve mass
n o n u n i f o r m i t y i m p a r t e d b y evolution. T h e t a p h o n o m i c features
m o r t a l i t y of m a n y individuals and species due to environmental
of trilobites (e.g., articulation of delicate skeletal e l e m e n t s ) m a y
crises (Brett and Seilacher 1 9 9 1 ) . T h e s e crises may include s t o r m
provide u n a m b i g u o u s evidence for episodic s e d i m e n t a t i o n ; c o n -
and seismic s h o c k events, volcanic eruptions such as those at
versely, highly c o r r o d e d fossil material provides a distinctive sig-
Pompeii, overturn of the water c o l u m n , and anoxia. However,
nature o f l o n g - t e r m c o n d e n s a t i o n .
only the m o r t a l i t y events associated with episodes of burial will
Articulated s p e c i m e n s o f trilobites, while generally u n c o m m o n , may be a b u n d a n t in s o m e beds. Moreover, the totally m i n -
be recorded as such. M o s t bodies decay rapidly after death, with a resultant loss of soft parts.
eralized body parts of trilobites c o m m o n l y have been preserved
Scavengers of all sorts are also part of the normal fauna, and
nearly u n c h a n g e d for at least 5 2 0 million years. However, preser-
a dead animal can be expected to b e c o m e a food source for a wide
vational features of fossil s p e c i m e n s can be used to decipher the
variety of o t h e r animals, which in Paleozoic seas included other
t a p h o n o m i c history of these s p e c i m e n s and provide useful clues
trilobites. T h e result of this is that a dead trilobite exposed on the
as to original e n v i r o n m e n t .
seafloor can be expected to b e c o m e disarticulated and the body
T h e structural c o m p l e x i t y of the trilobite exoskeleton and the
parts scattered within a relatively short period of time. C o n s e -
process of m o l t i n g of the exoskeleton d u r i n g growth increase the
quently, very shortly after death the animal must be buried at least
n u m b e r of fossil parts that can be generated by a single individ-
deeply e n o u g h
ual. Trilobite skeletal parts can be f o u n d in a m a j o r i t y of fossilif-
oxygen inhibits scavenging and also favors the preservation of
erous localities in New York, and well-preserved cephala and
intact skeletons.
pygidia are generally identifiable to species. W i t h most o r g a n i s m s , like bivalves or gastropods in which the skeletal growth is by
32
to physically inhibit disarticulation.
Lowered
DEATH,
DECAY,
AND
Soft Tissue Decay
m o n t h s . As such, skeletons m a y be completely disarticulated
T h e most destructive process to affect the bodies of o r g a n i s m s is the decay of soft parts. T h e most volatile parts are tissues, such as internal organs and muscle, and as a result such tissues are very rarely encountered as fossils. W h e r e they are preserved, it is usually (but not always: Butterfield 1 9 9 0 ) the result of early diagenetic mineralization (Allison 1 9 8 8 b ) . Anoxia historically has been viewed as a prerequisite for the preservation of such tissues (e.g., W h i t t i n g t o n 1 9 7 1 b ) . However, the removal of e n v i r o n m e n t a l oxygen does not prevent microbial activity ( B e r n e r 1 9 8 1 b ; Allison 1988a; Allison and Briggs 1 9 9 1 a ) . Microbes simply utilize a variety of alternative oxidants for carbon degradation. In fact, it has been suggested that anoxia may retard the decay process by only a factor of two or three (Canfield and Raiswell 1 9 9 1 a ) . M o r e importantly, anoxia prevents scavenging and favors early mineralization. T h e microbial reactions that are involved in anaerobic decay also generate a series of reactive e l e m e n t s , which in s o m e c i r c u m s t a n c e s can go on to produce early diagenetic minerals. T h e s e minerals, in turn, may preserve the decaying tissues themselves. T h e minerals most frequently associated with soft-part preservation are pyrite (Allison
33
DISARTICULATION
1 9 8 8 a ) , phosphate (Allison
1 9 8 8 b ; Briggs and Kear
1 9 9 3 ) , and carbonates. T h e activity of anaerobic bacteria is a necessity for the f o r m a t i o n of all three. F o r m a t i o n of organic-clay complexes or clay coatings may also be i m p o r t a n t in soft-part preservation (Butterfield 1 9 9 0 ) . Most well-preserved b e n t h i c fossils are preserved approximately at their life sites, so b o t t o m - w a t e r anoxia can be ruled out as a preservational factor. Allison's ( 1 9 9 0 ) calculations demonstrate that most o r g a n i s m bodies b e c o m e anoxic m i c r o e n v i r o n m e n t s internally during early phases of decay. I n h i b i t i o n of scavenging in these e n v i r o n m e n t s may p r o l o n g the association of skeletal elements. 1 lowever, even under conditions of a n a e r o b i o sis or anoxia, bacterial decay of ligaments is rapid and the slightest currents will serve to disarray pieces (Allison 1988a, 1 9 9 0 ) . Not surprisingly, most cases of soft-part preservation a m o n g trilobites are associated with dysoxic m u d r o c k facies, typically dark, slightly organic-rich shales. T h e Burgess Shale ( M i d d l e C a m b r i a n , British C o l u m b i a ) , Frankfort Shale (Beecher's Trilobite Bed, Upper O r d o v i c i a n , New Y o r k ) , and the Hunsriick Shale (Lower Devonian, G e r m a n y ) are a few of the m o s t notable e x a m ples (Allison and Briggs 1991a, 1 9 9 1 b , 1 9 9 3 ; see b e l o w ) .
within a period of a few m o n t h s or less ( P l o t n i c k 1986, Allison 1988a). A variety of articulated trilobite remains are f o u n d . Speyer and Brett ( 1 9 8 6 ) recognized three basic categories: ( 1 ) partially articulated exoskeletons, ( 2 ) m o l t remains or exuviae, and (3) c o m pletely articulated skeletons representing carcasses (Figure 3 . 1 ) . Partially
articulated
remains,
such
as
groups
of
thoracic
segments, are of i n d e t e r m i n a t e origin and may represent either partially decayed remains of carcasses or molt parts. Exuviae in m a n y trilobites are recognizable by the absence of specific structures. For m o s t trilobites m o l t i n g involves the shedding of free cheeks. T h e r e f o r e , articulated exoskeletons with cranidia lacking free cheeks are almost certainly exuviae. P h a copids had fused facial sutures and shed the entire cephalic shield in m o l t i n g . T h u s , articulated thoracopygidia ("headless trilob i t e s " ) suggest m o l t parts. Molt e n s e m b l e s are groups of closely associated m o l t parts, such as free cheeks lying in close p r o x i m ity to articulated r e m a i n s with cranidia, or cephalic shields closely associated with thoracopygidia in p h a c o p i d s . Carcasses are represented by completely articulated exoskelet o n s , with the cephala intact a n d articulated (i.e., free cheeks are i n t a c t ) . T h i s category m a y be subdivided f u r t h e r into o u t stretched or p r o n e s p e c i m e n s and in s o m e trilobite species, partially enrolled and fully enrolled individuals. O r g a n i s m s with m u l t i e l e m e n t skeletons, including trilobites, are particularly sensitive indicators of rapid
and p e r m a n e n t
burial. Well-preserved, articulated trilobites typically o c c u r on certain bedding planes within
m u d r o c k s that would not be
recognizable as event-beds by other sedimentological m e a n s . Because such skeletons c a n n o t b e reworked, the o c c u r r e n c e o f even a single intact s p e c i m e n of a trilobite is an excellent indicator that the enclosing sediment a c c u m u l a t e d rapidly and was not subsequently disturbed. T h e o c c u r r e n c e o f large n u m b e r s o f completely
articulated
trilobites
provides
dramatic
evidence
for a p o p u l a t i o n of o r g a n i s m s that was abruptly wiped out. Conversely, the o c c u r r e n c e of well-preserved molt ensembles need not imply any m o r t a l i t y but rather indicates burial under relatively low-energy c o n d i t i o n s
that
prevented
scattering of
parts. Certain widely traceable levels in the Middle Devonian H a m i l t o n G r o u p are characterized by a b u n d a n t articulated molt ensembles but few, if any, c o m p l e t e trilobites (that would represent carcasses). Such findings may reflect rapid a c c u m u l a t i o n of thin layers of s e d i m e n t that did not kill or s m o t h e r living trilo-
Articulated Remains
bites but were sufficient to preserve molts (Speyer 1 9 8 7 ) . M a n y assemblages of well-preserved trilobites are also d e m o n -
Skeletons of organisms in which the skeleton is c o m p o s e d of
strably in situ ( b u r i e d in their living sites). A particularly sensi-
multiple elements weakly b o u n d together by ligaments or m u s -
tive indicator is the o c c u r r e n c e of trilobite molt ensembles, that
culature, such as trilobites, are o n l y rarely preserved intact.
is, associated, disarticulated m o l t parts. It is virtually impossible
M o d e r n experimental studies indicate that the degradation of
for different disarticulated p o r t i o n s of the skeleton to be trans-
soft tissues in arthropods occurs within a period of a few hours
ported any distance and still remain associated. T h e hydrody-
after death, while destruction of ligaments ensues in weeks to
n a m i c properties of whole exuviae versus free cheeks would
FIGURE 3 . 1 . Fossil a s s e m b l a g e s reflecting various c o n d i t i o n s a n d timing of burial. A. Low rates of s e d i mentation a n d slow burial a l o n g with reworking of the prefossilized hard parts. Sclerites are broken a n d scatt e r e d . B. Slow burial with disarticulation a n d m i x i n g . C. O b r u t i o n : burial, under a thin blanket of sediment, with s o m e disarticulation a n d infaunal s c a v e n g i n g . D. O b r u t i o n : s u d d e n burial under a thick blanket of s e d iment, resulting in g o o d preservation of articulated fossils a n d r e d u c e d infaunal s c a v e n g i n g . A - D from Brett a n d Baird (1993). E. Trilobites that exhibit s o m e d e g r e e of disarticulation b e c a u s e they were not b u r i e d d e e p l y e n o u g h or soon e n o u g h after mortality, PRI 4 9 6 6 1 . F. A g r o u p of w e l l - p r e s e r v e d trilobites as a result of r a p i d , relatively d e e p burial, PRI 4 9 6 6 2 . G. A trilobite that is tightly c o i l e d a n d well p r e s e r v e d , PRI 4 9 6 6 3 . Trilobites c o i l e d under stress, p r o b a b l y a s s o c i a t e d with the burial event.
TRANSPORT
AND
35
REORIENTATION
be so different that it is extremely unlikely they could be trans-
downward
ported and yet end up together. Molt ensembles thus constitute
that m a y be interpreted as indicators of storm-generated scour
p r o o f of life activity (i.e., m o l t i n g ) by trilobites in the precise site
and fill.
o f burial. O t h e r dramatic examples of in situ trilobites are the very rare
or lateral-oblique
positions
along
linear
features
M a n y skeletal e l e m e n t s , including articulated trilobites, as well as their cranidia and pygidia, have approximately concavo-
specimens of articulated skeletons directly associated with their
convex dish-shapes. R a n d o m o r preferred c o n v e x - u p o r convex-
trace fossils, such as famous s p e c i m e n s of Flexicalymene attached
down
to Rusophycus (see Figure 2 . 1 4 B ) . T h e o c c u r r e n c e of beds of en-
assemblages,
rolled trilobites also suggests a behavioral response to stressed
c o n d i t i o n s . Instances o f r a n d o m o r nearly o n e - t o - o n e ratios o f
orientations and
may each
be has
observed distinct
in
different
implications
trilobite
for
burial
conditions in which trilobites may have b u r r o w e d into the sedi-
c o n v e x - u p and - d o w n o r i e n t a t i o n s o c c u r primarily in heavily
m e n t and enrolled themselves, only to be buried in place and
b i o t u r b a t e d sediments, w h e r e , in addition, skeletal elements may
apparently unable to escape from m u d blanketing.
display lateral or edgewise o r i e n t a t i o n s . T h e m i x i n g of skeletal
Speyer and Brett ( 1 9 8 5 ) also recognized species-segregated
c o m p o n e n t s into sediment m a y a c c o u n t for the randomizing
clusters of fully articulated skeletons ( " b o d y clusters"; Plates 5 9 ,
of o r i e n t a t i o n . However, such o r i e n t a t i o n s are unstable under
102, 147, and 152) and m o l t e n s e m b l e s ( " m o l t clusters") involv-
hydrodynamic currents and h e n c e , are probably o n e of the better
ing at least three species of trilobites on single bedding planes in
indicators o f b i o t u r b a t i o n o r s o m e type o f protective c o n c e n t r a -
the Devonian Hamilton G r o u p . T h e s e trilobite clusters appear
tion trap on the substrate.
to represent preserved behavioral patterns. Using the a r g u m e n t
C o n c a v o - c o n v e x trilobite skeletal e l e m e n t s and whole bodies,
that the molt ensembles could not have been t r a n s p o r t e d any dis-
like
tance, Speyer and Brett inferred that these represented species-
c o n v e x - d o w n o r i e n t a t i o n s . For e x a m p l e , cephala and pygidial
segregated aggregations of trilobites that molted en mass. Speyer
shields in a preferred c o n v e x - u p position are p r o b a b l y most
and Brett further pointed out that synchronized m o l t i n g typically
typical
serves as a prelude to m a t i n g in m o d e r n peracarid crustaceans
Hesselbo 1987, Lask 1 9 9 3 ) showed that even gentle currents will
(e.g., marine isopods) and that several species also m a y t i m e their
affect trilobite r e m a i n s resting on the seafloor in such a way that
m a n y shells, c o m m o n l y display preferred c o n v e x - u p or
of c o n c e n t r a t e d
trilobite
beds.
Flume
studies
(e.g.,
reproductive cycles to a c o m m o n external stimuli, such as lunar
they flip to a hydrodynamically stable o r i e n t a t i o n , at which point
cycles. This analog suggests that trilobite clusters may represent
currents will glide over their s t r e a m l i n e d , c o n v e x - u p surfaces.
preserved mating "orgies."
T h e effect is particularly evident in areas of m u d d y substrate because o f the i m p e d a n c e (i.e., frictional d r a g ) .
Transport and Reorientation Trilobite skeletons can be sensitive indicators of hydrody-
Hence,
the
occurrence
of
abundant
convex-up
trilobite
cephala or pygidia on bedding planes m a y provide evidence for reworking of skeletal material under slightly current-agitated
namic conditions in the depositional e n v i r o n m e n t . U n d e r low-
conditions.
energy e n v i r o n m e n t s , typical of m u d r o c k s , o r g a n i s m remains
was processed by o n e or m o r e s t o r m - g e n e r a t e d current events.
may be buried in situ. O n e might use the a r g u m e n t that well-
Excellent examples are f o u n d in large assemblages of Flexicaly-
Beds of this sort represent skeletal material that
articulated fossils such as trilobites must not have been trans-
mene and Isotelus pygidial
and cephalic
ported and that their o c c u r r e n c e therefore indicates quiet water
o f h u m m o c k y laminated
calcisiltite beds, and
environments, but this inference must be m a d e cautiously. Aside
Pseudogygites
from obvious cases where this is not so (e.g., in which these skele-
in prep.).
from
the
Ordovician
shields on
the bases
pavements o f
Collingwood
Shale
(Brett,
tons are found at the bases of turbidites or even within skeletal
Beds of preferentially c o n c a v e - u p w a r d trilobite t a g m a are not
grainstone deposits), there is experimental evidence that if o r g a n -
as c o m m o n . In settings where the m o l t parts are suspended
isms are transported within the first few hours following death,
briefly and allowed to resettle from suspension, they will almost
their remains may stay articulated. Allison ( 1 9 8 6 ) d e m o n s t r a t e d
invariably settle c o n c a v e - u p w a r d (Lask 1 9 9 3 ) . Such reorienta-
in tumbling barrel e x p e r i m e n t s that a r t h r o p o d s such as s h r i m p ,
tion would o c c u r in areas very close to s t o r m wave-base in which
which provide possible analogs to trilobites, m a y be potentially
the
moved even tens of kilometers without disarticulating, provided
materials t e m p o r a r i l y o f f the b o t t o m and allow t h e m to free-fall
that this happens within the first few hours following their
b a c k to the substrate. Rapid burial following this stirring would
demise.
i n c o r p o r a t e such shells as a basal pavement of a possibly graded
Trilobite fossils also may provide evidence for reworking or
rather
gentle
storm-generated
waves
would
lift skeletal
m u d s t o n e layer. Excellent e x a m p l e s of this m o d e of burial are
transport of skeletons that would otherwise remain unsuspected.
seen
in
pavements of Triarthrus cranidia
in
Ordovician dark
It is not unusual in m a r i n e m u d r o c k s to observe c o n c e n t r a t i o n s
shales. C o u n t s of m a n y bedding planes from the Ordovician
of shells in localized pockets, typically associated with evidence
C o l l i n g w o o d Shale of O n t a r i o show a p r e d o m i n a n c e of concave-
for current scour. Such a c c u m u l a t i o n s c o m m o n l y display c o n v e x -
upward o r i e n t a t i o n s of the cranidia and of tiny ostracode valves,
36
TAPHONOMY
even on bedding planes in which larger skeletons are r a n d o m
slightly, by currents after death. As noted already, however, c u r -
o r c o n v e x - u p w a r d ( C . Brett, unpublished o b s e r v a t i o n , 1 9 9 8 ) . W e
rents usually have the effect of flipping concavo-convex elements
suggest that under certain c o n d i t i o n s only the smallest, light-
to a preferred convex-upward position. If trilobite remains were
weight skeletons were suspended and then resettled—typically
lifted into a current slightly and then resettled, they might still
concave-upward.
assume this position. Also, the generation of decay gasses within
Stacks of nested or shingled fossils apparently o c c u r where
the b o d y cavities of trilobites might give t h e m slight buoyancy
densely packed skeletal r e m a i n s were affected by oscillatory,
and make t h e m m o r e subject to the lifting and settling required
s t o r m - g e n e r a t e d waves or currents, and provide an indication
to invert the carcasses. All such inferences seem to point to a b r i e f
of deposition well within s t o r m wave-base. A similar m o d e of
interlude between m o r t a l i t y and final burial.
involves c o n c a v o - c o n v e x
A few o c c u r r e n c e s of p r e d o m i n a n t l y convex-upward out-
shells bundled together in nested groupings, either c o n v e x -
preservation
in
shell
accumulations
stretched trilobites are also k n o w n ; for example, groupings of
upward or -downward and often b o t h in the s a m e layers. T h e s e ,
Eldredgeops milleri f r o m the Silica Shale typically show this o r i -
too, seem to reflect the effects of settling and c o n c e n t r a t i o n of
e n t a t i o n . T h e s e are c o m m o n l y associated with perfectly enrolled
skeletal remains during t u r b u l e n c e events, and they are c o m -
trilobites and they m a y represent examples of m o r e nearly instan-
m o n l y associated with m i n o r s e d i m e n t grading. An intriguing
t a n e o u s burial with little disturbance.
example consists of masses of nested cephalic and pygidial shields
Speyer ( 1 9 8 7 ) and B r a n d t ( 1 9 8 5 ) also considered the possi-
of bumastid trilobites from Silurian b i o h e r m s , such as those in
bility of preferential orientation of enrolled trilobites but c a m e
the Silurian I r o n d e q u o i t L i m e s t o n e . T h e s e m a y represent molt
to different c o n c l u s i o n s .
parts that were c o n c e n t r a t e d in sheltered " p o c k e t s " or scours on
o r i e n t a t i o n s in s o m e mass occurrences of enrolled Flexicalymene
b i o h e r m surfaces.
meeki f r o m Upper Ordovician shales of the C i n c i n n a t i , O h i o ,
Brandt
reported essentially r a n d o m
A particularly intriguing a n d still e n i g m a t i c aspect of o r i e n t a -
region. In contrast, Speyer recognized preferred and species-
tion in trilobites is the p r e d o m i n a n t l y c o n c a v e - u p w a r d (dorsal
specific o r i e n t a t i o n s in Devonian enrolled trilobites from New
shield d o w n )
York.
o r i e n t a t i o n o f articulated trilobites. M a n y o c c -
Greenops
s p e c i m e n s were
commonly found
a
cluding
the
showed cephalon-lateral or -downward positions. Speyer sug-
Ordovician Trenton L i m e s t o n e of New York (Brett et al. 1 9 9 9 ) ,
gested that these findings recorded different modes of pre-enroll-
beds
m e n t behavior by the trilobites.
occurrences
of Dalmanites
(Taylor and
Brett
limulurus
of Ceraurus pleurexanthemus in
the
Silurian
from
Rochester
Shale
Eldredgeops rana
in
cephalon-up
mass
position, while
most
urrences of clusters of trilobites display this p h e n o m e n o n , in-
more commonly
1 9 9 6 ) , and aggregations of Eldredgeops rana
T h e preferred azimuthal ( c o m p a s s bearing) orientation o f
from the f a m o u s trilobite beds of the Lake Erie region (Speyer
elongate skeletons has been the subject of n u m e r o u s studies,
and Brett 1 9 8 5 ) . Several explanations for such o r i e n t a t i o n s have
including
been put forth. R a y m o n d ( 1 9 2 0 a ) believed that these represented
Kidwell a n d B o s e n c e 1 9 9 1 , for s u m m a r y ) . From such studies, it
both
observational
and
experimental
studies
(see
examples of trilobites buried in a life position, postulating that
has b e c o m e c o m m o n knowledge that elongate particles typically
these animals swam upside down, like horseshoe crabs, and per-
o r i e n t themselves selectively within a current. Elongate objects
ished in this position. However, m o s t later a u t h o r s have c o n s i d -
that do not roll, such as the trilobite carcasses m e n t i o n e d earlier,
ered this unlikely and argued for a p o s t m o r t e m reorientation of
c o m m o n l y will be aligned parallel to the direction of the current.
carcasses. O n c e again, if the c o n c a v o - c o n v e x carcasses of trilo-
Such may be the case with consistently aligned specimens of C.
bites were suspended and resettled freely, they would very likely
pleurexanthemus reported by Brett et al. ( 1 9 9 9 ) . T h e o c c u r r e n c e
assume this position. Several features associated with the dorsal-
of s o m e aligned trilobites in elongated "windrows," such as in the
downward trilobites m a y bear on this issue. F o r e x a m p l e , Speyer
Silurian Rochester Shale, may represent accumulation in very
and Brett ( 1 9 8 5 ) n o t e d that s o m e o f the " i n v e r t e d " trilobites were
m i n o r scours o r gutters (Whiteley and Smith 2 0 0 1 ) .
headless and thus, likely molted thoracopygidia. Such s p e c i m e n s obviously were not " s w i m m i n g , " and yet they are f o u n d alongside c o m p l e t e specimens that are also p r e d o m i n a n t l y c o n v e x - d o w n -
Fragmentation and Biased Preservation
ward. Even a m o n g these latter s p e c i m e n s there m a y be signs of
Trilobite skeletal elements are variably affected by biotic and
incipient disarticulation (e.g., c e p h a l o n or pygidium is rotated
abiotic destructive agents p o s t m o r t e m . T h e degree to which the
slightly away f r o m thorax; t h o r a c i c s e g m e n t s are very slightly
skeletons are affected is a function not only of the delicacy of their
pulled a p a r t ) . Such observations suggest that the trilobites repre-
original c o n s t r u c t i o n but also of residence t i m e on the seafloor.
sent carcasses that had u n d e r g o n e a very slight a m o u n t of decay
O n c e e l e m e n t s are disarticulated, they may be acted on by
prior to burial. In all of the a b o v e - m e n t i o n e d cases, there is also
various hydrodynamic processes that serve to sort, fragment,
a vaguely to strongly preferred long-axis o r i e n t a t i o n (e.g., see
abrade, or c o r r o d e t h e m . H y d r o d y n a m i c size sorting is u n c o m -
Brett et al. 1 9 9 9 ) . T h i s would also seem to imply that the trilo-
m o n in m o s t m u d r o c k s , for which generally low-background
bites reflect carcasses or m o l t s that were t r a n s p o r t e d , if only
e n v i r o n m e n t a l energies are characteristic. However, size sorting
FOSSIL
37
DIAGENESIS
may o c c u r on the scale of a single graded bed as a result of tur-
exposure t i m e , as well. Conversely, s o m e shells in condensed
bulent events that briefly suspend skeletal particles and sediment
deposits show few, if any, epibionts. M i c r o b o r i n g s of forms such
and allow them to resettle.
as endolithic algae may be recognized and may provide particu-
Biased ratios of skeletal parts, for which original p r o p o r t i o n s
larly useful indicators of exposure a n d , in s o m e cases, of relative
are known to have been o n e - t o - o n e , m a y provide evidence of
depth ( G o l u b i c et al. 1 9 7 5 ; Vogel et al. 1 9 8 7 ) . Endolithic algae of
sorting or, m o r e frequently in the case of m u d r o c k s , of preferen-
various sorts, for e x a m p l e , are c o n f i n e d to various p o r t i o n s of the
tial destruction. For e x a m p l e , it is a c o m m o n observation that
e u p h o t i c to upper dysphotic zone. Algal m i c r o b o r i n g s in Dicra-
certain portions of trilobite skeletons are preferentially preserved,
nurus s p e c i m e n s have been used to suggest that these trilobites
whereas the others tend to be f r a g m e n t e d . T h i s results in a selec-
lived in the e u p h o t i c zone. Kloc ( 1 9 9 7 ) suggested that abundant
tive bias that is not related to size but rather to relative robust-
encrusters on the cephalic spines of these trilobites may have
ness of the skeletal parts. For e x a m p l e , the rather robust pygidia
settled during the life of the trilobite and served as camouflage
of dalmanitids and asaphids are m o r e c o m m o n l y preserved intact
against visual predators.
than are cephala. Pygidia-cephala ratios up to t e n - t o - o n e were found in s o m e spectacular bedding plane pavements of Pseudogygites latimarginatus from the C o l l i n g w o o d Shale in O n t a r i o ( C . Brett, unpublished d a t a ) . Conversely, for the small trilobite Tri-
Fossil Diagenesis: Geochemical Processing of Potential Fossils
arthrus eatoni, from the same beds the small, fragile pygidia are
Early diagenetic p h e n o m e n a c o m p r i s e the physicochemical
very rare, and s o m e bedding planes show n o t h i n g but cranidia
processes that act on o r g a n i s m r e m a i n s primarily after burial.
("head shales"). Beds with approximately o n e - t o - o n e ratios of
Diagenetic features of fossils m a y provide i n f o r m a t i o n regarding
cephala and pygidia may indicate rather rapid and intact burial,
the g e o c h e m i s t r y o f b o t t o m waters and the upper " t a p h o n o m i -
whereas those that show a strongly biased ratio probably repre-
cally active z o n e " ( T A Z ) of the sediment c o l u m n . Diagenetic fea-
sent time-averaged a c c u m u l a t i o n s in which rather long exposure
tures of note include evidence for early dissolution, c o m p a c t i o n ,
times on the sea b o t t o m prevailed. D u r i n g these intervals, m i n o r
and mineralization of fossils.
physical disturbances, such as multiple s t o r m s or even biotic disturbances, fragmented the less rigid skeletal parts preferentially.
T h e relative t i m i n g of dissolution is c o m m o n l y recorded in skeletons. Trilobite exoskeletons were i m p r e g n a t e d with calcite and thus are relatively resistant to dissolution and are preservable;
Abrasion, Corrosion, and Encrustation
however, they still
may show evidence of early dissolution.
Trilobite skeletons that are dissolved prior to c o m p a c t i o n may
It is often difficult to distinguish between trilobite skeletons
leave no record but, in m a n y cases, m a y be preserved as plasti-
that have been physically abraded and those that have been
cally d e f o r m e d molds (Seilacher et al. 1 9 8 5 ) . Such preservation
corroded by biogeochemical processes. As a generalization most
would indicate u n d e r s a t u r a t i o n with respect to calcite in the
trilobite remains are too fragile to withstand p r o l o n g e d abrasion,
upper s e d i m e n t s and possibly low pH c o n d i t i o n s . Conversely,
and this fragility may a c c o u n t for the rarity of trilobite skeletons
many f o s s i l skeletons and their molds display mosaic fracture
in s o m e nearshore, sandy e n v i r o n m e n t s in which trace fossils indi-
patterns on their surfaces; these are particularly p r o m i n e n t on
cate that trilobites were c o m m o n . It is well k n o w n that clay-sized
large shields such as the cephala and pygidia of Isotelus species.
sediment is ineffective as an abrasive agent. H e n c e , truly abraded
Such skeletons r e m a i n e d hard in early phases of c o m p a c t i o n ,
fossils are rare in m u d r o c k s and, if f o u n d , might indicate a m u c h
which caused brittle fracture. (In rare instances, both plastically
m o r e c o m p l e x history to the deposit in which shells were trans-
d e f o r m e d " g h o s t e d " s p e c i m e n s and brittly fractured (or unfrac-
ported into a quieter water e n v i r o n m e n t by a turbulent event.
tured)
well-calcified
specimens
occur
on
the s a m e bedding
C o r r o d e d trilobite remains tend to o c c u r in offshore, low-
planes. Such associations have been used to suggest the presence
energy e n v i r o n m e n t s , and b i o e r o s i o n , likewise, tends to p r e d o m -
o f " s o f t - s h e l l e d " ( i m m e d i a t e l y p o s t m o l t ) and intermolt individ-
inate over physical abrasion in these offshore settings (Kidwell
uals (Speyer 1 9 8 7 ) . )
and Bosence 1 9 9 1 ; Parsons and Brett 1 9 9 1 ) . M a n y apparently
Early diagenetic minerals such as siderite, calcite, and pyrite
abraded shells in m u d r o c k s probably have been chemically etched
generally f o r m as a result of the action of anaerobic bacteria
or acted on by m i c r o b o r i n g o r g a n i s m s .
and are partly c o m p o s e d of their respiratory b y - p r o d u c t s (Allison
Even in life, trilobite exoskeletons may b e c o m e encrusted with epibiontic organisms, such as b r y o z o a n s and even b r a c h i o p o d s
1 9 8 8 a ) . T h e y m a y provide valuable i n f o r m a t i o n o n sediment g e o c h e m i s t r y and rates of burial.
(Tetreault 1992; Kloc 1993; Taylor and Brett 1 9 9 6 ) . P o s t m o r t e m
O n e o f the best u n d e r s t o o d o f the early diagenetic minerals
trilobite remains may be encrusted both externally and internally.
is pyrite, iron disulfide ( B e r n e r 1981a; Canfield and Raiswell
Internal encrustation provides an excellent indication that skele-
1 9 9 1 a , 1 9 9 1 b ) . Pyrite is c o m m o n in m a n y m a r i n e m u d r o c k s and
tons have lain disarticulated for a period of t i m e on the sea
is c o m m o n l y associated with fossil trilobite remains. T h e ferrous
b o t t o m . T h e extent o f encrustation may provide a n indicator o f
iron required in pyrite f o r m a t i o n is available in terrigenous
38
TAPHONOMY
sediments, and dissolved sulfate is a b u n d a n t in m a r i n e water (but
as a
not in fresh water). Under aerobic decay of organic matter, the
the m o s t c o m m o n trilobite in these beds, and s o m e specimens
m a j o r respiratory b y - p r o d u c t s o f o r g a n i s m s are water ( H 0 ) and
are partially pyritized and have a solid pyritic core and s o m e
c a r b o n dioxide ( C O , ) .
However, under a n a e r o b i c c o n d i t i o n s
coiled s p e c i m e n s form the nucleus of a pyrite nodule. These beds
particular types of bacteria, referred to as sulfate-reducing bacte-
appear to represent the rapid burial of organism bodies in an o t h -
ria, use sulfate ( S 0 ~ ~ ) as an oxygen d o n o r for metabolizing
erwise l o w - o r g a n i c sediment. T h e high c o n c e n t r a t i o n of pyritic
:
4
nucleus for over-pyrite precipitation.
Greenops grabaui is
organic matter, and p r o d u c e hydrogen sulfide ( H , S ) and bicar-
material a r o u n d burrows and fossils indicates nucleation around
b o n a t e ( H C 0 " ) as b y - p r o d u c t s . Iron r e d u c t i o n , mediated by a
local centers of a n a e r o b i c decay associated with buried organic
second group of a n a e r o b i c bacteria, can generate ferrous ions,
matter.
3
which in turn m a y react with the H , S generated by sulfate reduc-
A n a e r o b i c decay processes, including sulfate reduction, also
tion, to produce the precursors of pyrite (Canfield and Raiswell
generate H C O , " ( b i c a r b o n a t e ) , which may initiate the precipita-
1991 b ) . T h e presence of pyrite shows that the s e d i m e n t was anoxic
tion of calcite or siderite c o n c r e t i o n s around decaying organic
but does not necessarily d e m o n s t r a t e that the overlying water
matter. W h e r e trilobites or other fossils are enclosed within car-
c o l u m n was anoxic. Pyrite can f o r m either very early or relatively
b o n a t e c o n c r e t i o n s , they are nearly always t h r e e - d i m e n s i o n a l .
late in the burial history of a sediment ( H u d s o n 1 9 8 2 ; Brett and
T h i s proves that the c o n c r e t i o n s f o r m e d early and before organ-
Baird 1 9 8 6 ; Allison 1 9 8 8 a , 1 9 8 8 b ; Canfield a n d Raiswell 1 9 9 1 a ) .
ism remains could be c o m p a c t e d by overburden pressure.
Under c o n d i t i o n s o f high o r g a n i c - m a t t e r p r o d u c t i o n , anoxic
It is less c o m m o n for phosphatic nodules to form because
c o n d i t i o n s may e x t e n d into the water c o l u m n ; in such euxinic set-
p h o s p h o r u s is only present in very small quantities in seawater.
tings H , S is in excess, and any iron that is i n t r o d u c e d into the
However, the a n a e r o b i c decay of organic matter does liberate
system is pyritized as it is deposited. T h u s , pyrite tends to be
phosphate-bearing
distributed evenly in the s e d i m e n t as disseminated tiny crystal
can b e c o m e a d s o r b e d to ferrous hydroxides in the sediment.
aggregates called framboids; it is n o t c o n c e n t r a t e d a r o u n d any
As these ferrous hydroxides are buried and pass through the
o r g a n i s m remains that m a y settle into these settings. U n d e r oxic
anoxic-oxic
b o t t o m - w a t e r c o n d i t i o n s , however, o r g a n i c material is not dis-
liberates phosphates to pore-water. Dissolved phosphate m a y
tributed so u n i f o r m l y because m u c h of it is degraded aerobically
be released b a c k to the water c o l u m n if anoxia persists to the
at or near the s e d i m e n t - w a t e r interface, a n d the sediment b e -
s e d i m e n t - w a t e r interface. However, if a micro-oxidized zone
c o m e s anoxic b u t nonsulfidic, in Berner's ( 1 9 8 1 a ) terminology.
exists in the upper s e d i m e n t , then the phosphates may be repre-
T h u s , pyritization tends t o o c c u r m o r e locally within the n o n -
cipitated, especially a r o u n d phosphatic skeletal nuclei, such as
sulfidic s e d i m e n t , particularly in the vicinity of anaerobically
the
decaying organic matter. As a result of local sulfate r e d u c t i o n ,
(Swirydczuk et al. 1 9 8 1 ; B e r n e r 1981a; Allison 1 9 8 8 b ) . Trilobites
sulfide is liberated a r o u n d this d e c o m p o s i n g organic material.
are not u n c o m m o n l y phosphatized. Phosphatization of trilobites
Dissolved iron will react at the site of sulfate r e d u c t i o n so that
occurs primarily under c o n d i t i o n s of slow sedimentation. T h u s ,
pyrite is restricted to a n o x i c o r g a n i c - r i c h m i c r o e n v i r o n m e n t s
for e x a m p l e , in the M i d d l e Devonian Hamilton G r o u p , p h o s -
within a broadly dysoxic, l o w - o r g a n i c setting. Well-preserved
phatized internal m o l d s of enrolled trilobites may o c c u r at m i n o r
pyritized fossils, including trilobites tend to o c c u r in b i o t u r b a t e d
disconformities.
compounds
boundary,
chitinophosphatic
they
are
material
to
solution.
reduced.
forming
Also,
This
phosphate
process
arthropod
also
skeletons
gray m u d s t o n e s and thus are indicators of b o t t o m - w a t e r oxy-
If the s e d i m e n t a t i o n rate is high, then the time spent by any
genation (Brett and Baird 1 9 8 6 ; Allison and Brett 1 9 9 5 ) . T h e ear-
particular s e d i m e n t layer at this micro-oxidized interface will be
liest phases of pyrite tend to be fine-grained fillings of cavities,
low, and the p h o s p h o r u s c o n c e n t r a t i o n in pore-water will be
such as the interiors of enrolled trilobites. Later generations of
increased only slightly. Conversely if the sedimentation rate is
larger crystalline " o v e r p y r i t e " may nucleate on existing pyritic
low, then the t i m e spent at the interface will be high. T h u s , a large
cores. In this way, pyritic nodules m a y f o r m (Figure 3 . 2 ) . T h e r e are a n u m b e r of M i d d l e D e v o n i a n fossil beds in New
p r o p o r t i o n o f the a d s o r b e d p h o s p h o r u s c o m p o u n d s will b e c o n centrated at o n e layer in the sediment. Such c o n c e n t r a t i o n can
York wherein large a m o u n t s of pyrite are f o u n d associated with
increase pore-water levels of p h o s p h o r u s so that phosphate m i n -
the fossils ( D i c k and Brett 1 9 8 6 ) . T h e best k n o w n of these is the
erals can precipitate. T h e s e minerals may replace organic remains
Alden Pyrite Beds in the Ledyard Shale. T h e Ledyard Shale is
o r f o r m c o n c r e t i o n s . T h u s , the o c c u r r e n c e o f phosphatic fossil
a dark-gray, generally poorly fossiliferous shale. However, a
molds or c o n c r e t i o n s is nearly always an indicator of low rates of
h o r i z o n in the lower Ledyard in western New York is rich in pyrite
sedimentation.
nodules and pyritized m o l d s o f fossils o f all sorts. M o s t c o m m o n
O t h e r f o r m s o f diagenetic modification o f trilobite material
are the fossils that had calcific or aragonititic shells in life, such
are u n c o m m o n to absent in New York. T h e r e are a few references
as pelecypods, b r a c h i o p o d s , nautiloids, a m m o n o i d s , and trilo-
to silica replacement of exoskeletal material in trilobite protaspids
bites. T h e pyrite nodules have fossils at their core, which indicates
b u t n o observations o f phosphate replacement o r carbonized
that the original pyrite, f o r m e d f r o m the organic decay, acted
specimens.
FIGURE 3.2. Conditions for the formation of pyritized, w e l l - p r e s e r v e d fossils. A. Fauna on a b o t t o m with poor oxygenation. There is low diversity, a n d the b o t t o m is anoxic a short d i s t a n c e b e n e a t h the s u r f a c e . The plus s i g n s (+) indicate anoxic conditions. B. R a p i d burial by s e d i m e n t a n d the r e d u c e d o x y g e n levels of the water raise the anoxic level to the newly b u r i e d o r g a n i s m s . A n o x i c bacteria in m e t a b o l i z i n g o r g a n i c matter of the trilobites also r e d u c e the sulfate in the pore water, resulting in sulfide ions that then react with r e d u c e d ( F e ) iron in the sediment. In a s e d i 2+
ment rich in terrigenous material, the iron level is high e n o u g h to c a u s e iron sulfide precipitation at or c l o s e to the d e c a y i n g organic material. C. Pyrite a c c u m u l a t e s at the source of the o r g a n i c decay, a n d the fossil is c o v e r e d with pyrite at this nucleation site. A - C from Speyer a n d Brett (1991). R e p r o d u c e d with p e r m i s s i o n . D, A trilobite b u r i e d in a rapid burial event but in an o x y g e n a t e d s e d i m e n t so that only a minor a m o u n t of pyrite f o r m e d . E. A coiled trilobite buried under anoxic, low-organic ( e x c e p t at the site of trilobite d e c a y ) , a n d iron-rich c o n d i t i o n s , resulting in a total c o v e r i n g of pyrite, PRI 4 9 6 6 4 .
40
TAPHONOMY M o r e c o m p l e t e i n f o r m a t i o n on the processes of fossil preser-
plete typically outstretched, inverted individuals may occur, even
vation can be f o u n d in collective volumes edited by Briggs and
in clusters. U n d e r lower sedimentation the event signature c o m -
C r o w t h e r ( 1 9 9 0 ) ; Allison and Briggs ( 1 9 9 1 a , 1 9 9 1 b ) ; D o n o v a n
prises primarily intact molt e n s e m b l e s , with few if any fully artic-
( 1 9 9 1 ) ; Einsele, Ricken, and Seilacher ( 1 9 9 1 ) ; a n d M a r t i n ( 1 9 9 9 ) .
ulated carcasses. Finally, under low-energy, dysoxic (background) c o n d i t i o n s , intact molt parts and tagma are the rule; the event signature of this setting is distinctive in showing an abundance
Trilobite Taphofacies
o f enrolled, c o m m o n l y pyritized, s p e c i m e n s o f trilobites.
Various aspects of fossil preservation can be c o m b i n e d into
Each taphofacies records different types of i n f o r m a t i o n . T h e
the recognition and description of t a p h o n o m i c facies or t a p h o -
distinctive m o d e s of preservation provide i n f o r m a t i o n on sedi-
facies (Speyer and Brett 1 9 8 6 , 1 9 9 1 ) . Together with lithofacies,
m e n t a r y e n v i r o n m e n t s that c a n n o t be determined otherwise.
biofacies, and ichnofacies, taphofacies tend to vary predictably
F o r e x a m p l e , the e n r o l l m e n t of trilobites may reflect a response
with sedimentary e n v i r o n m e n t s , as shown by studies in m o d e r n
to toxic stimuli triggered by a stirring up of anoxic, sulfide-rich
marine settings (Parsons and Brett 1 9 9 1 ) . T h e m o d e s o f preser-
m u d s . Similarly, pyritization suggests burial in anoxic, low-
vation of fossils can provide i m p o r t a n t insights into a n u m b e r of
organic m u d s .
features o f m u d r o c k deposition, including ( 1 ) the s e d i m e n t a r y
In this way, the study of trilobite preservation has helped to
e n v i r o n m e n t (depth, t e m p e r a t u r e , salinity, oxygen level, substrate
provide a new tool in paleoenvironmental analysis. Development
consistency);
of predictive models relating preservation to depositional envi-
(2)
the
dynamics
of
sediment
accumulation,
average rates, as well as evidence for episodicity of s e d i m e n t a t i o n
r o n m e n t s and positions in sedimentary sequences, in turn, may
and erosion;
aid
(3)
the temporal scope o f individual m u d r o c k
units; and ( 4 ) the s e d i m e n t g e o c h e m i s t r y and early diagenetic
paleontologists
in
prospecting
for
new fossil
bonanzas,
including spectacular trilobite beds.
environments. T h e overall c o n d i t i o n of trilobite skeletons can be assessed qualitatively or quantitatively but certainly should be n o t e d in the
Trilobite Lagerstatten
field. Semiquantitative indices can be f o r m u l a t e d by d e t e r m i n i n g
Lagerstatten (derived from the G e r m a n mining term trans-
the p r o p o r t i o n of skeletal parts in different, arbitrarily defined
lated loosely as " m o t h e r lodes") are extraordinary fossil assem-
preservational states. In such cases, it is c o m m o n l y useful to
blages. Trilobite Lagerstatten include o b r u t i o n deposits, reflecting
determine a set of standards with which particular shells can be
a rapid s m o t h e r i n g of benthic faunas by sediment, yielding fully
c o m p a r e d and assigned to a category, in m u c h the s a m e way that
articulated remains and Konservat-Lagerstatten, in which even
grain shapes and roundness indices have long been assessed on
soft parts are preserved by a c o m b i n a t i o n of rapid burial, anaer-
the basis of standardized profiles by sedimentologists. Skeletal
o b i c decay, and early diagenetic mineralization (Seilacher et al.
condition is particularly valuable for recognizing qualitatively
1 9 8 5 ) . In this section we describe examples of trilobite Lager-
the differing relative extents of s e d i m e n t a r y time-averaging and
statten f r o m New York State to illustrate the general t a p h o n o m i c
therefore, may be related to burial rates.
concepts.
In their original f o r m u l a t i o n of the n o t i o n of taphofacies,
A f a m o u s trilobite site is Beecher's Trilobite Bed in the Upper
Speyer and Brett ( 1 9 8 6 ) used M i d d l e Devonian trilobites and
Ordovician Frankfort F o r m a t i o n just north of R o m e , New York.
their modes of preservation to exemplify the general m o d e l . T h e y
A 5 - m m - t h i c k , light-gray layer within a dark-gray m u d s t o n e
also subsequently emphasized the fact that fossils in a particular
contains an unusual collection of fossil material (Cisne 1 9 7 3 ) .
taphofacies may show b o t h b a c k g r o u n d and event t a p h o n o m i c
The
signatures. That is, there may be distinct aspects of preservation
appendages and s o m e internal organs replaced by pyrite. B e e c h e r
Triarthrus
eatoni
specimens
within
this
layer
have
their
of fossils under day-to-day c o n d i t i o n s or under episodic cata-
( 1 8 9 3 , 1 8 9 4 , 1 8 9 5 ) reported the discovery by Valiant and the
strophic burial c o n d i t i o n s in a given e n v i r o n m e n t (Speyer and
preparation o f specimens. Cisne ( 1 9 7 5 , 1981) prepared very-
Brett 1 9 8 8 ) . T h e well-known D e v o n i a n trilobite species E. rana
high-resolution radiographs of Beecher's specimens and was able
and Greenops species o c c u r in m a n y distinct associations repre-
to report on internal structures never seen before. W h i t t i n g t o n
senting different e n v i r o n m e n t s . Yet, these trilobites show very dis-
and A l m o n d ( 1 9 8 7 ) also e x a m i n e d specimens from the beds and
tinctive m o d e s o f c o m m o n
suggested that certain structural elements of the appendages were
preservation that are u n i q u e t o
particular o n s h o r e - o f f s h o r e positions and s e d i m e n t a t i o n c o n d i -
utilized in food t r a n s p o r t , a m o n g other things. Replacement of
tions. For example, in high-energy shallow water, m o s t trilobite
organic tissue in such high resolution by pyrite is very unusual.
remains are disarticulated, abraded f r a g m e n t s , although articu-
Briggs, Bottrell, and Raiswell ( 1 9 9 1 ) e x a m i n e d these trilobites and
lated, typically outstretched individuals may o c c u r occasionally,
concluded that this type of soft tissue replacement was due to
owing to pulses of burial. In low-energy, fully oxic settings,
bacterial decay in anoxic c o n d i t i o n s resulting in sulfide f o r m a -
mainly u n b r o k e n , t h o u g h typically disarticulated trilobite m a t e -
tion. T h e rocks represent deep-water turbidites, and anything
rial is preserved; under episodes of higher s e d i m e n t a t i o n , c o m -
buried probably would have been subject to anoxic conditions.
TRILOBITE
LAGERSTATTEN
41
T h e concentration of organic matter in the sediment was rela-
b i o t u r b a t e d . A possible explanation is that the subsequent thicker
tively low, and the c o n c e n t r a t i o n of iron in the pore-water rela-
beds were deposited a short t i m e after this o n e , essentially sealing
tively high. In this situation the sulfide produced at local decay
it and m a k i n g any decay anaerobic. T h e low level of iron in the
sites was precipitated as an iron m o n o s u l f i d e (a precursor to
sediment precluded significant pyrite f o r m a t i o n .
pyrite) at the site where it was f o r m e d , resulting in the nearly perfect
replacement
Edgecombe
of
soft
tissue
by
pyrite
(Briggs
T h i s f o r m of appendage preservation
is unique and was
and
only f o u n d when Walcott m a d e sections of the trilobites and
1 9 9 3 ) . Beecher's Trilobite Bed remains the most
observed t h e m by t r a n s m i t t e d light. T h e very fine calcite in-filling
productive source of preserved trilobite soft tissue k n o w n .
in a c a r b o n a t e m a t r i x is very difficult to see and evaluate by
Trilobites found on limestone bedding planes typically are
reflected light. T h i s difficulty raises the question as to whether
compressed for the same reasons that trilobites are c o m p r e s s e d
this m o d e of preservation is actually m o r e c o m m o n but gener-
on shale partings. T h e i r history is similar in that they were buried
ally unobserved.
by a calcareous m u d f l o w with little t r a n s p o r t . S o m e of the best
T h e Lower Silurian R o c h e s t e r Shale c o n t a i n s several horizons
trilobites, however, from the physical preservation standpoint, are
yielding n u m e r o u s trilobites. S p e c i m e n s of the large lichid genus
found within limestones. In s o m e instances, these trilobites were
Arctinurus, when articulated, are usually f o u n d right side up but
apparently caught up in a calcareous sediment flow, killed, p r o b -
flattened.
ably transported s o m e distance, and e n t o m b e d in the settled
always inverted and often o c c u r s in narrow, elongate " w i n d r o w s "
sediment. In such limestones the trilobites typically are r a n d o m l y
that may show s o m e evidence of a preferred o r i e n t a t i o n . T h e
oriented, with the bodies flexed in unusual postures, and retain
living Arctinurus a n i m a l s probably were buried in place by a
much
of
their
original
three-dimensional
character.
Dalmanites
limulurus,
from
several
layers,
is
almost
Large
heavy blanket of s e d i m e n t , which resulted in their death. T h e D.
numbers of Isotelus gigas have been taken from the limestones of
limulurus, however, were t r a n s p o r t e d s o m e w h a t before the burial
the Middle Ordovician Trenton G r o u p in central New York. T h e
process, aggregated, and c u r r e n t aligned in windrows. T h e fact
specimens from bedding planes are flattened and c o m m o n l y
that most are upside d o w n is less easily explained. Convex surface
upside down, while those from within the limestone retain their
down may be a preferred o r i e n t a t i o n d u r i n g transport in a
three-dimensional character.
c u r r e n t , or the living a n i m a l m a y have been t u m b l e d by the
In the Walcott-Rust Q u a r r y within the Trenton G r o u p , several
current and the u p s i d e - d o w n trilobites m a y not have been able
layers of the thinly bedded limestone have yielded excellent trilo-
to right themselves. Again, alignment probably indicates slight
bites (Brett et al. 1 9 9 7 , 1 9 9 9 ) . O n e thin micritic limestone yielded
transport of dead individuals by a c u r r e n t . Alternatively, it is pos-
large
sible that these trilobites swam upside down to escape the sedi-
numbers
of articulated
C.
pleurexanthemus,
Flexicalymene More
m e n t and were buried in this p o s i t i o n . A possible model for this
than 9 8 % of the trilobites on the base and those within the layer
latter behavior c o m e s from the living h o r s e s h o e c r a b , Limulus,
were upside down while 6 0 % o f those o n the upper surface,
which n o r m a l l y crawls a r o u n d the b o t t o m but m o r e rarely swims
including many that were still partially within the l i m e s t o n e , were
upside d o w n .
senaria, and
Meadowtownclla
trentonensis
(but
no
I.
gigas).
right side up. T h e t h i n n e r bed probably records a large popula-
T h e siltstones,
m u d s t o n e s , shales, and
limestones
Hamilton
yielded
of the
tion of trilobites caught in a current and transported far e n o u g h
Middle
to be mixed within the small a m o u n t of sediment involved. M o s t
n u m b e r s o f articulated s p e c i m e n s o f trilobites. O n e well-studied
of the trilobites were killed in the process. T h e larger m o r e robust
bed, the B r o w n s C r e e k B e d , a lime m u d s t o n e in the lower C e n -
ones may have managed to struggle to the surface and die there
terfield
or were covered and killed by a subsequent event. T h e observa-
Monodcchenella
tion that no /. gigas were involved suggests that they were large
b e d can be traced f r o m Centerfield, O n t a r i o C o u n t y , to East
Devonian
Limestone,
yields
macrocephala,
Group
superbly and
have
preserved
Pseudodechenella
enormous
Eldredgeops
rana,
rowi.
This
and strong enough to escape. Two other, thicker beds had no
Bethany, G e n e s e e C o u n t y , a distance of over 4 9 k m (31 miles).
trilobites on the base or top but well-preserved s p e c i m e n s inter-
T h e trilobites are f o u n d in r a n d o m o r i e n t a t i o n , indicating they
nal to the limestone. T h e s e internal trilobites, which included /.
were swept up, t u m b l e d , and t r a n s p o r t e d s o m e distance from
gigas, were randomly oriented.
their original position in the sudden event f o r m i n g this bed.
Within the thin bed, coiled and semicoiled C. pleurexanthemus and F. senaria were discovered by C. D. Walcott ( w h o also discovered
the
Burgess
was
Wanakah
and
the
Windom
rana. Especially notable are the " G r a b a u Trilobite B e d s " (lower
This unique m o d e of preservation is believed to result from
Creek and the S m o k e C r e e k Beds in the f o r m e r P e n n - D i x i e
anoxic
the
Q u a r r y at H a m b u r g , Erie C o u n t y . T h e s e trilobite beds yield
appendage, followed by calcite in-filling as the appendage m a t e -
t h r e e - d i m e n s i o n a l clusters of E. rana, which Speyer and Brett
precipitation
evidence
lower
W a n a k a h Shale) along the Lake Erie shore near Eighteenmile
calcite
there
the
of
induced
and
within
appendages preserved as calcite infillings (Walcott 1876, 1 8 7 7 b ) . bacterially
Shale),
Horizons
m e m b e r s of the H a m i l t o n G r o u p are especially productive of E.
within
rial decayed (Brett et al. 1997, 1 9 9 9 ) . T h e Ceraurus bed is a thin,
( 1 9 8 5 ) divided into molt and b o d y clusters. T h e clusters are
15 to 5 0 - m m bed that normally would be expected to be heavily
nearly intact, which suggests little t r a n s p o r t . T h e s e beds are the
42
TAPHONOMY
result of very rapid burial and death, with very little turbulence
of 5 to 20 individuals are k n o w n . T h e general preservation is
d u r i n g the burial event.
similar to that of the M u r d e r Creek Beds.
T h e E. rana s p e c i m e n s from the lower W a n a k a h M u r d e r Creek
In s u m m a r y , t a p h o n o m i c analysis is a m a j o r factor in under-
Beds are f o u n d tightly coiled, fully o u t s t r e t c h e d , and in various
standing trilobite deposits, as well as fossil deposits in general.
semicoiled configurations in between these two e x t r e m e s . Typi-
T h e understanding that c o m e s from such analyses not only is
cally, in the semicoiled s p e c i m e n s , the pygidium appears to be
intellectually rewarding but also provides a foundation for inter-
missing. On close e x a m i n a t i o n , however, the pygidium can always
preting the geological history of fossil sites. T h e r e is also a
be f o u n d inside the body cavity of the trilobite. It is suggested
predictive factor that c a n n o t be ignored. For example, storm
that the pygidium was displaced when the tightly coiled trilobite,
deposits over stable sea b o t t o m s , below storm wave-base, often
u p o n decay, partially o p e n e d and viscous m u d filled the n o w -
b u r y a living fauna, resulting in well-preserved articulated fossils
e m p t y cavity.
such as trilobites and crinoids. Fossil preservation provides
T h e trilobites in the f o r m e r P e n n - D i x i e Q u a r r y are mostly in
the interpretation of fossil deposits and
the S m o k e Creek Beds o f the W i n d o m M e m b e r n a m e d for their
a n c i e n t e n v i r o n m e n t s . T a p h o n o m y and its concepts are power-
outcrop on S m o k e Creek, Erie C o u n t y . Well-preserved individ-
ful tools for general fossil collectors as well as professional
ual trilobites are c o m m o n in these beds, and occasional clusters
paleontologists.
1
1
i m p o r t a n t clues in
The Penn-Dixie Quarry is a public fossil site operated by the Hamburg
Natural History Society (P.O. Box 7 7 2 , Hamburg, NY 1 4 0 7 5 ; 7 1 6 - 6 2 7 - 4 5 6 0 ) .
4
The Paleozoic Geology of New York
T h e Paleozoic strata of New York State are a classic repository of
they c a n n o t be u n d e r s t o o d in isolation from the region as a
fossils, including, at m a n y levels, trilobites and a host of o t h e r
whole. D u r i n g this interval, present-day New York lay generally
invertebrate and even vertebrate and plant fossils. For details on
in southern subtropical to w a r m t e m p e r a t e latitudes, with the
the paleoecology and fossils, we r e c o m m e n d the publications
equator
by Linsley ( 1 9 9 4 ) , Isachsen et al. ( 1 9 9 1 ) , Landing ( 1 9 8 8 ) , Shaw
C l i m a t e s ranged from hot and arid to warm and h u m i d during
( 1 9 6 8 ) , and the references therein.
this t i m e .
running
approximately
centrally
through
Laurentia.
T h e purposes of this chapter are twofold: first, to give the reader both s o m e general b a c k g r o u n d regarding the tectonic, climatic, and paleoenvironmental history of life on earth (Archean through Pleistocene, Figure 4 . 1 A ) , and m o r e specifically of New York State and adjacent ancestral North A m e r i c a during the early
Prelude to the Paleozoic: Late Proterozoic Collisions and the Grenville Orogeny T h e oldest rocks in New York, exposed in the Adirondack
to middle Paleozoic Era ( C a m b r i a n through D e v o n i a n , Figure
M o u n t a i n s and the
4 . I B ) , the time during which trilobites lived and were deposited
than 1 billion years old. T h e s e are crystalline rocks that were
Hudson
Highlands, are s o m e w h a t m o r e
in New York's sedimentary rocks; and second, to provide s o m e
m e t a m o r p h o s e d or altered from older rocks by e n o r m o u s heat
details on the stratigraphy, sedimentology, and paleoecology of
and pressure (Figure 4 . 2 ) . S o m e were originally igneous rocks,
the intervals from Early C a m b r i a n to Middle Devonian that have
f o r m e d from the c o o l i n g and crystallization o f m a g m a s , and
yielded abundant trilobite remains. To these ends, the discussion
others are s e d i m e n t a r y deposits, such as q u a r t z sandstones,
of each Paleozoic t i m e interval is subdivided into two p o r t i o n s :
limestones,
first, an overview of global and New York geological history, and
phosed) by recrystallization and under intense heat and pressure;
and
shales.
T h e s e were
transformed
(metamor-
second, details of the stratigraphy and sedimentary e n v i r o n m e n t s
for example, sandstones were altered to tough metaquart/ites,
of the trilobite-bearing intervals, listed chronologically. Such
limestones to m a r b l e s , and shales to m i c a - r i c h schists. By looking
general discussion of geology might seem out of place in a b o o k
at the types of minerals f o r m e d within these rocks by m e t a m o r -
devoted to trilobites; however, we believe that students of New
p h i s m , geologists can be certain that the rocks now exposed in
York's trilobites should be well aware of these b r o a d e r contexts
the Adirondacks were o n c e buried up to 25 km within Earth
in order to understand the e n v i r o n m e n t s and ecology ot these
during a great o r o g e n i c or m o u n t a i n - b u i l d i n g e p i s o d e — a b o u t a
remarkable ancient o r g a n i s m s .
billion years ago. T h i s event, the Grenville Orogeny, apparently resulted when the (present) eastern edge of ancestral North
Overview T h e Paleozoic deposits of New York record a p o r t i o n of the
America
was overridden
by a n o t h e r c o n t i n e n t , perhaps the
northwestern side ot" present-day South America. This e n o r m o u s collision helped to weld together a supercontinent known as
history of ancestral North America or Laurentia during s o m e
P r o t o p a n g e a or Rodinia (Figures 4.3 and 4 . 4 ) . For nearly half a
2 0 0 million years of geologic t i m e (Figure 4 . I B ) , and as such,
billion years, this s u p e r c o n t i n e n t held together, and the massive •13
A
FIGURE 4 . 1 . A. Time scale for Earth history a n d for life on Earth. The New York Paleozoic is from the early C a m b r i a n to the e n d of the D e v o n i a n . A d a p t e d from S. M. Stanley, Exploring Earth and Life through Time. New York: W. H. Freeman, 1989. B. G e n e r a l i z e d g e o l o g y a n d detailed scale for the Paleozoic rocks in New York. The vertical scale is linear a n d proportional to time; note that the d a t e s of b e g i n n i n g s a n d e n d s of periods are given in millions of years before present. The right c o l u m n s list the n a m e s of major unconformities a n d the n a m e s of Sloss s u p e r s e q u e n c e s . Most of the information is from a n u m b e r of s o u r c e s . The d a t e s for the C a m b r i a n are from D a v i d e k et al. (2000) a n d L a n d i n g et al. (1998a,b). The T in the C a m b r i a n time p e r i o d indicates where trilobites first a p p e a r in the fossil r e c o r d , 5 1 9 million years before present. The d a t e s in the E p o c h s are the most current. The d a t e s in the Stages h a v e yet to be r e c o n c i l e d in the literature.
45
OVERVIEW
B
Grenville m o u n t a i n belt, fully f o r m e d by a billion years ago, was
present eastern seaboard region (eastern Massachusetts, eastern
exposed in a life-less continental interior to the forces of weath-
Nova Scotia, eastern N e w f o u n d l a n d ) , Florida, California, and
ering and erosion. We know that by about 5 5 0 million years ago,
o t h e r marginal areas that were added later. Laurentia was isolated
an entire thickness of continental crust had b e e n removed and
as a separate c o n t i n e n t during rifting and o p e n i n g of new ocean
erosion had exposed the roots of the ancient Grenville M o u n t a i n s .
basins that began approximately 7 0 0 to 6 0 0 million years ago
Laurentia is the term geologists apply to the ancestral Paleo-
during the interval of t i m e referred to as late P r o t e r o z o i c (or N e o -
zoic core of N o r t h A m e r i c a , lacking certain areas such as the
p r o t e r o z o i c ) . Notably, on the present east side of Laurentia,
THE
46
PALEOZOIC
GEOLOGY
OF
NEW
YORK
FIGURE 4 . 2 . P r e c a m b r i a n Grenville ( 1 . 0 BP) m e t a m o r p h i c / i g n e o u s rocks. Note the granitic pegmatite (a) and smaller folded dikes (b) cutting g n e i s s . Rte. 12, near Alexandria Bay, J e f f e r s o n County.
rifting or fracturing of the crust began over 6 0 0 million years
Initially, a large v o l u m e of sediment that eroded from the
a g o — s o m e 4 0 0 million years after the Grenville Orogeny. T h e
ancient Grenville terrane was shed o f f the old weathered craton
fractures and faults ultimately tore the s u p e r c o n t i n e n t of Rodinia
and into the n a r r o w Iapetus basin. However, as the sea level c o n -
apart. Evidently, ancestral S o u t h A m e r i c a , which had collided
tinued to rise during the latest Proterozoic and Early C a m b r i a n ,
with p r o t o - L a u r e n t i a to f o r m the Grenville M o u n t a i n s , n o w
the old land was finally flooded and the source of sediments cut
pulled back away. A new o c e a n , the Iapetus, or P r o t o - a t l a n t i c ,
o f f (Figure 4 . 5 A ) . T h e entire eastern b o r d e r of Laurentia had
began to open along a line that would pass through present-day
b e c o m e a passive continental edge; a sea with a very broad c o n -
central
tinental shelf ultimately extended from the area of central New
New
Carolinas, a
England bit
east
and of the
southward Blue
Ridge
to
the
east-central
Mountains
in
the
Appalachian chain (these m o u n t a i n s f o r m e d later).
England and the m i d Atlantic states region westward to the present Mississippi Valley during the C a m b r i a n to Early O r d o v i -
At the b e g i n n i n g of the Paleozoic Era, a b o u t 5 4 5 million years
cian (Figure 4 . 5 A , B ) . As spreading ensued in the Iapetus m i d o -
ago, a narrow, but widening Iapetus O c e a n lay slightly to the east
cean rift, the ocean basin grew wider, at least up to the Early
of present-day New York State (Figure 4 . 5 A ) . East of the present
Ordovician t i m e , about 4 8 0 million years ago, before the process
Berkshire ( M a s s a c h u s e t t s ) and Green ( V e r m o n t ) M o u n t a i n s lay
began to reverse and the Iapetus basin began to shrink and
the edge of Laurentia, w h i c h , m u c h like the present eastern edge
ultimately close.
of modern North A m e r i c a , f o r m e d a continental shelf bordered eastward (southward at that t i m e ) by a relatively steep d r o p - o f f along a continental slope into the deep water of the Iapetus Ocean.
Cambrian Period T h e C a m b r i a n Period, as it is now dated, spans approximately
Seawater was displaced upward o u t of the Iapetus O c e a n ,
54 million years from about 5 4 3 to 4 8 9 million years before
partly because of the e x p a n d i n g m i d o c e a n ridge ( o r spreading
present. Yet this was o n e of the most significant times in the
center, an area of hot upwelling m a g m a ) . T h i s seawater spread
history of life, for it was during this time that nearly all phyla or
out o n t o the c r a t o n of Laurentia and caused a m a j o r rise of the
m a j o r groups of a n i m a l s appeared in the rock record.
shoreline (transgression) up o n t o the old weathered r e m n a n t s of the Grenville rocks.
T h e onset of the C a m b r i a n was marked by a time of lowdiversity fossil assemblages typified by "small shelly" skeletons
FIGURE 4.3. M a p s h o w i n g the extent of the Grenville belt in eastern North A m e r i c a . Rocks in this area were d e f o r m e d a n d m e t a m o r p h o s e d about 1 billion years a g o . The d o t t e d pattern s h o w s regions w h e r e Grenville rocks are buried b e n e a t h y o u n g e r strata; the slanted lines indicate areas w h e r e Grenville rocks are e x p o s e d ; a n d cross-hatching shows areas where the Grenville rocks are d e f o r m e d by later o r o g e n i e s . M o d e r n A d i r o n d a c k Mountains lie just to the east of the Frontenac A r c h ( l a b e l e d ) . From Isachson et al. (1991). Printed with permission of the New York State M u s e u m , Albany, N.Y.
•18
THE
PALEOZOIC
GEOLOGY
OF
NEW
YORK
FIGURE 4 . 4 . P a l e o m a g n e t i c reconstruction of the supercontinent Rodinia as it existed in the late Proterozoic, a b o u t 7 0 0 million years a g o . Note the position of Laurentia, near the center. The dark belt shows the position of the Grenville O r o g e n i c belt. After Dalziel (1997), r e p r o d u c e d with permission.
including a variety of calcareous p h o s p h a t i c tubes, rods, and
divided
plates. O n l y in later Early C a m b r i a n t i m e ( - 5 1 9 millon years ago)
a u t o c h t h o n o u s ( n o n t r a n s p o r t e d ) rocks, which are in the site
into two great packages of strata
(Figure 4 . 7 ) . T h e
did trilobites first appear as body fossils, although fossil track-
of original deposition, a shallow-shelf e n v i r o n m e n t , and the
ways (traces of walking on the b o t t o m ) and resting pits (Ruso-
Taconic
phycus) suggest that unpreserved s o f t - b o d i e d trilobites, or similar
shales (now often slates) that were originally deposited to the east
a r t h r o p o d s , o c c u r r e d earlier.
of New York in o c e a n i c e n v i r o n m e n t s . T h e Taconic rocks were
T h e C a m b r i a n rocks of New York State are generally s u b -
allochthonous
transported
westward
(displaced)
80km
rocks,
during
the
mostly deep-water
Middle
Ordovician
CAMBRIAN
PERIOD
49
FIGURE 4 . 5 . Position of the Laurentian plate and neighboring Baltica and Avalonia terranes from the Cambrian to the Devonian. Areas of e x p o s e d land are dark, a r e a s c o v e r e d by water a r e white, a n d New York is highlighted in black. A. Middle Cambrian as most of what is the United S t a t e s w a s beginning to be flooded by shallow s e a s resulting in c a r b o n a t e depositions in the Late C a m brian (note Taconic island a r c s ) . B. Middle Ordovician with almost c o m p l e t e flooding of Laurentia and the beginning of the Taconic Orogeny with collision in the s o u t h e a s t . C. Silurian, with Baltica colliding with Laurentia from the e a s t . Also note the smaller "islands of Avalonia." D. Middle Devonian, with the A c a d i a n O r o g e n y fully d e v e l o p e d d u e to collision of the Avalon t e r r a n e s ; note heavy sedimentation from the e a s t e r n mountains. Modified from Witzke ( 1 9 9 0 ) . R e p r o d u c e d with permission.
Taconic Orogeny (a m a j o r m o u n t a i n - b u i l d i n g event) along m a j o r
continental shelf. Following the interval of rifting that produced
thrust faults. T h i s d e f o r m a t i o n apparently was related to the
the Protoatlantic or Iapetus O c e a n , the continental shelf, which
convergence of an island arc c o m p l e x with eastern Laurentia ( o r
is represented by the region f r o m New England westward into
ancestral North A m e r i c a ) .
central New York, u n d e r w e n t rapid subsidence due to cooling. L i m e m u d and silt probably were produced by o r g a n i s m s such as
Cambrian Autochthon T h e a u t o c h t h o n o u s rocks o f the central Appalachians, which
algae, the growth of which was evidently able to keep up with the rate of subsidence so that these shelf e n v i r o n m e n t s remained in very shallow water, above the n o r m a l wave-base. C a m b r i a n to
include basal sandstone and limestone or d o l o s t o n e , represent
Early
extensive shallow, subtropical platform seas, s o m e t i m e s referred
carbonates—the
Ordovician
rocks
to as the Great American Tidal Flat (Figures 4 . 5 , 4 . 7 ) . In s o u t h -
by major unconformities.
Sauk
form
a
package
Sequence—bounded
of sandstones above
and
and below
eastern New York and southern Pennsylvania these beds may be
D u r i n g C a m b r i a n and Early O r d o v i c i a n t i m e , eastern North
up to 5 km thick and were mainly deposited in very shallow, tide-
A m e r i c a lay in a subtropical position, perhaps 25° south of
influenced e n v i r o n m e n t s . T h e i m m e n s e thickness is a c c o u n t e d
the p a l e o e q u a t o r (Figure 4 . 5 ) . Today this zone is known as the
for by active subsidence, or downward sinking, of the C a m b r i a n
"subtropical desert b e l t " because it is here that s o m e of the driest
FIGURE 4.6. C a m b r i a n rocks in New York. A. U p p e r C a m b r i a n P o t s d a m S a n d s t o n e at Ausable
Chasm
near
Plattsburg,
Clinton
County.
B.
Tilted
Precambrian-Cambrian
(Lippalian) nonconformity. A p p r o x i m a t e l y 500 million years of n o n d e p o s i t i o n a n d erosion s e p a r a t e dark a m p h i b o l i t e s (a) ( m e t a m o r p h i c rocks) from the light gray, U p p e r C a m b r i a n Little Falls Formation (b). Cut a l o n g U.S. Rte. 5S near Fonda, M o n t g o m e r y County.
CAMBRIAN
51
PERIOD
conditions on Earth develop. T h e r e is s o m e evidence that ances-
stone of the M o h a w k Valley, the Hoyt L i m e s t o n e of the Saratoga
tral North America in the C a m b r i a n was relatively arid in the
area, the Whitehall F o r m a t i o n of Lake G e o r g e , and the Theresa
(present) eastern regions. T h e r e is also evidence for the buildup
D o l o s t o n e of the Saint Lawrence region are carbonates: lime-
of slight hypersalinity in the C a m b r i a n waters. C a m b r i a n d o l o -
stones, and d o l o s t o n e s , f o r m e d very late in the C a m b r i a n or in
stones contain vugs and s o m e t i m e s m o l d s of evaporite crystals
earliest O r d o v i c i a n t i m e (Figures 4.7 and 4 . 9 ) . T h e y display an
such as gypsum, anhydrite, and halite. T h e o c c u r r e n c e of o o i d s
a b u n d a n c e o f stromatolites. S o m e o f the most f a m o u s stromato-
(small spherical, concentrically ringed c a l c i u m c a r b o n a t e grains)
lites in the n o r t h e a s t e r n part of North A m e r i c a o c c u r in the
and stromatolites ( m o u n d l i k e structures f o r m e d o f sediment
Petrified G a r d e n s within the Hoyt Limestones near Saratoga
trapped by cyanobacteria or blue-green algae) also is typical of
Springs, New York (Figure 4 . 9 ) .
hypersaline (elevated-salinity) waters in the subtropics today.
T h e Little Falls F o r m a t i o n stromatolitic dolostones (up to
Whatever the case, m u c h of the C a m b r i a n seafloor in the New
30 m thick) are only very sparsely fossiliferous. O n l y a single free
York area was relatively low in shelly o r g a n i s m s .
c h e e k of the trilobite Elvinia has been f o u n d from the C a m b r i a n
T h e broad continental shelf of the C a m b r i a n sea was bordered
Little Falls F o r m a t i o n , but this is sufficient to bracket its age
to the east, in what are today central V e r m o n t , western Massa-
within the s e c o n d to last or F r a n c o n i a n Stage of the C a m b r i a n .
chusetts, and C o n n e c t i c u t , by an abrupt slope into deeper water.
( T h e Little Falls is noted for its characteristic vugs or cavities that
In the region flanking the continental shelf of N o r t h A m e r i c a ,
contain beautiful, doubly t e r m i n a t e d q u a r t z crystals referred to
sediments accumulated very gradually (Figures 4.7 and 4 . 9 ) .
as H e r k i m e r D i a m o n d s ; such crystals f o r m e d m u c h later during deep burial of the Little Falls sediments.) Just why most Upper C a m b r i a n c a r b o n a t e s are so p o o r in b o d y fossils, including trilo-
Cambrian Trilobite-Bearing Autochthonous Rocks T h e lowest and shallowest-water deposit of the C a m b r i a n
bites, but rich in stromatolites is as yet unclear. It may be that
a u t o c h t h o n o u s rocks belong to the Potsdam S a n d s t o n e or equiv-
the seas were s o m e w h a t hypersaline. However, the Hoyt L i m e -
alent sandy Little Falls F o r m a t i o n (Figures 4.6 and 4 . 8 ) . T h e
stone c o n t a i n s not only the f a m o u s stromatolites but also beds of
Potsdam Formation consists of up to 140 m of clean quartz a r e n -
oolitic l i m e s t o n e and s o m e fossiliferous limestone
ites or quartzose sandstones that display c r o s s - s t r a t i f i c a t i o n ,
sclerites (skeletal pieces) of trilobites b e l o n g i n g to a n u m b e r
ripple marks, and other features indicative of deposition in
of Late C a m b r i a n species are f o u n d ; Ludvigsen and Westrop
shallow-wave
and
sometimes
tide-dominated
environments
(Figure 4 . 8 ) . T h e Potsdam sediments represent sand eroded from deeply weathered areas of the N o r t h A m e r i c a n c r a t o n . The
presence
of
herringbone
cross-stratification
in which
( 1 9 8 3 ) recently described these species f r o m the Hoyt and Galway limestones. T h e s e trilobites are associated with o t h e r fossils, including
(inclined
b r a c h i o p o d s , m o l l u s c a n f r a g m e n t s , and even plates of the world's
bedding formed by alternate migration of ripples in opposite
oldest c h i t o n s . T h i s diverse assemblage indicates relatively favor-
directions) is an indication of the oscillatory currents associated
able, n o r m a l - s a l i n i t y c o n d i t i o n s in the area of Saratoga Springs
with tidal action. S o m e p o r t i o n s display large-scale trough cross-
during this p e r i o d . However, relative high energy due to wave
bedding and may represent w i n d - f o r m e d sand dunes in coastal
action and slow deposition prevented the easily disarticulated
areas.
trilobites f r o m being preserved whole. T h e trilobites o f the
The Potsdam is generally sparse in body fossils, although trace
Galway and Hoyt are:
fossils (burrows, tracks, and trails) of a variety of forms are present, including the bizarre and huge (by C a m b r i a n standards)
GALWAY
Climactichnites. T h i s elongate trail up to 3 0 c m ( o r m o r e than a
Calocephalites
foot) wide closely resembles m a r k s m a d e by a tractor tire in soft
Dellea
sand. This trace is found in flat-bedded sands that may represent
Drabia cf.
FORMATION
cf.
C.
minimus
saratogensis D.
menusa
Cameraspis Drabia
cf.
Elvinia
convexa D.
curtoccipita
granulata
the upper foreshore or beach. Just what large o r g a n i s m in the C a m b r i a n was able to c o m e out into very shallow water is quite
HOYT
unclear. Traces may have been preserved by the sun drying ini-
Delicti?
tially wet sands of coastal areas. Yochelson and F e d o n k i n ( 1 9 9 3 )
Keithiella
argued that it might have been a large gastropod-like mollusk. In
Pie tho pelt is sara togensis
Prosaukia
hartti
slightly m o r e offshore Potsdam f a d e s , trace fossils such as verti-
Prosaukici
Saratogia
(Saratogia)
cal
shafts
(Skolithos)
and
U - s h a p e d burrows
(Diplocraterion)
LIMESTONE
landingi depressa tribulis
Hoytaspis Pletlwpeltis
speciosa granulosa calcifera
are
quite abundant. Lingulid b r a c h i o p o d s and small fragments of trilobites also have been o b t a i n e d in a few levels, but in general body fossils are rare.
Cambrian of the Taconic Allochthon Initially, a substantial a m o u n t of silt, sands, and muds was
T h e higher beds of the Upper C a m b r i a n and those straddling
swept from the Grenville b a s e m e n t of Laurentia, which had been
the Ordovician b o u n d a r y are c a r b o n a t e s . T h e Little Falls D o l o -
exposed to weathering and erosion for over 4 0 0 million years.
FIGURE 4.7. N e w York in the C a m b r i a n . A. New York in the U p p e r C a m b r i a n , s h o w i n g the c a r b o n a t e bank over m u c h of the state. B. Cross section of the plate m o v e m e n t d u r i n g the U p p e r C a m b r i a n . C. Stratigraphic chart of the C a m b r i a n e x p o sures in N e w York. From Isachsen et al. (1991). Printed with p e r m i s s i o n of the New York State M u s e u m , Albany, N.Y.
CAMBRIAN
53
PERIOD
FIGURE 4 . 8 . C l o s e - u p of Upper Cambrian P o t s d a m S a n d s t o n e showing s e t s of c r o s s - b e d d e d quartz-rich s a n d s t o n e . Cut along Street, Whitehall, Washington County.
T h e coarser sands derived from this erosion a c c u m u l a t e d in
ing redox (oxidation states) c o n d i t i o n s on the seafloor. At certain
nearshore areas to form the Potsdam S a n d s t o n e facies (Figures
intervals, the b o t t o m water seems to have been better oxygenated,
4.8 to 4 . 1 0 ) .
However, substantially larger a m o u n t s of fine-
grained sediment (clay minerals) were either carried in dilute sus-
leading to the d e v e l o p m e n t of reddish or green slates with little o r n o a c c u m u l a t e d organic m a t t e r (Figure 4 . 1 0 ) .
pensions to offshore areas, where they settled o u t as h e m i p e l a g i c " r a i n " of m u d , or perhaps were blown offshore d u r i n g dust storms, eventually to settle out and a c c u m u l a t e as deep-water deposits.
Cambrian Trilobite-Bearing Allochthonous Rocks T h e green and purple Early C a m b r i a n shales or slates of the T a c o n i c M o u n t a i n s (up to 6 0 0 m t h i c k ) are c o m m o n l y quarried
T h e rocks that were deposited in the continental slope and rise
as roofing slates in eastern New York and V e r m o n t , but these
belt are no longer found in their area of original a c c u m u l a t i o n .
quarries are not m a j o r fossil localities. In general, it appears that
Rather, they are found as a series of thrust sheets that lie east of
relatively few o r g a n i s m s
the Hudson River Valley in present eastern New York, referred to
C a m b r i a n t i m e , and m o s t slates are b a r r e n , even as life was just
inhabited
the deep sea
during the
as the Taconic M o u n t a i n s (see under O r d o v i c i a n ) . T h e earliest,
bursting forth in shallow-shelf settings. Very few fossils have been
pretrilobite, portion of the C a m b r i a n is poorly recorded in New
f o u n d within these beds, although an unusual b r a n c h i n g trace
York. However, s o m e of the thick, m u d d y sandstones and silt-
fossil, Oldhamia, is a b u n d a n t in s o m e of the purple shales low in
stones of the high Taconic M o u n t a i n s may represent this t i m e
the T a c o n i c succession. T h e s e very small trace fossils may repre-
interval.
sent s o m e of the earliest deep-water grazing animals. A few local-
T h e low or western p o r t i o n s of the Taconics display well-
ities
have
yielded
trilobites.
The
Lower
Cambrian
Middle
preserved successions of C a m b r i a n - E a r l y Ordovician strata that
Granville or Nassau F o r m a t i o n , in the vicinity of Troy, Rensselaer.
comprise a series of alternating green to purple or black slaty
County,
shales (Truthville, Browns Pond, Middle Granville). T h e alterna-
asaphoides as well as a fairly c o m p l e t e growth series of this trilo-
tion between purple, green, and black m u d r o c k s indicates differ-
bite. T h e Lower C a m b r i a n trilobites found are:
has
yielded
articulated
remains
of
Elliptocephala
FIGURE 4 . 9 . U p p e r C a m b r i a n limestones. A. U p p e r C a m b r i a n limestone, Whitehall Formation. Note the darker gray oolitic limestone (a) in s h a r p c o n t a c t with fine-grained " r i b b o n limestone" (b). Also note the small stromatolite (c) a t t a c h e d to the U p p e r c o n t a c t of the oolitic limestone. Warner Hill Cuarry, Whitehall, W a s h i n g t o n County. B. D o m a l stromatolites ( " c r y p t o z o a n " ) in u p p e r C a m b r i a n Hoyt Formation. C r y p t o z o a n l e d g e , Petrified G a r d e n s R o a d , Lester Park, S a r a t o g a County.
CAMBRIAN
PERIOD
55 nant or when productivity in the surface waters was increased, allowing the a c c u m u l a t i o n of organic matter. T h e s e intervals also contain beds of l i m e s t o n e breccia or angular c o n g l o m e r a t e s that represent debris flows broken f r o m the edge of the continental shelf that avalanched d o w n into deeper water. Actually, a rather diverse fauna o f trilobites has b e e n o b t a i n e d f r o m s o m e o f the l i m e s t o n e breccias o r c o n g l o m e r a t e s . T h e dark facies include the Lower C a m b r i a n Browns Pond F o r m a t i o n and the Lower to Upper C a m b r i a n Hatch Hill Form a t i o n (a 1 5 0 - m interval of dark slaty shales) (Figures 4 . 6 C and 4 . 1 1 ) . B o t h units c o n t a i n n u m e r o u s interbeds of several types, including ripple cross-stratified sandstones that probably record turbidites. T u r b i d i t y c u r r e n t s (masses o f suspended sediment that flow d o w n s l o p e u n d e r the influence of gravity) swept finegrained siliciclastic silt and sand o f f of shelf regions into the deeper water. A n o t h e r c o m m o n type o f b e d consists o f lightgray weathering b a n d s of very fine-grained l i m e s t o n e . Careful e x a m i n a t i o n of s o m e of these beds reveals that they contain very fine l a m i n a t i o n s or even c r o s s - l a m i n a t i o n s and display sharp bases. T h e r e f o r e , they have been inferred to have been deposited as relatively dilute turbidites of suspended c a r b o n a t e silt and m u d that were e x p o r t e d into the deeper water f r o m the carb o n a t e b a n k near the top of the slope. Such deposits rarely contain fossils, t h o u g h trilobite fragments are k n o w n from s o m e turbidites. A n o t h e r type o f a c c u m u l a t i o n within the Taconic dark
shale
Perhaps
consists
the
"Schodack
best
of brecciated
known
Limestone"
of these
found
near
(fragmented) is
the
limestones.
Lower
Castleton
Cambrian
Cutoff
in
the
Hudson Valley. Relatively few o r g a n i s m s could actually live in the low-oxygen deeper waters.
But the remains of shallow-water
o r g a n i s m s were abruptly t r a n s p o r t e d into s o m e o f these envir o n m e n t s as debris flows from the shallow-shelf regions above where these a n i m a l s lived. T h e fossiliferous breccia beds are a key to the stratigraphy of the lower part of the T a c o n i c rocks. T h e s e thin limestone-clast c o n g l o m e r a t e s contain a sandy m a t r i x that yields a b u n d a n t fossils of a variety of trilobites, including agnostids, b r a c h i o p o d s , and s o m e of the world's oldest bivalves. T h e s e fossils, particularly the trilobites, are invaluable for dating the succession. A few Lower C a m b r i a n a l l o c h t h o n o u s rocks are rich with fragFIGURE 4 . 1 0 . Simplified stratigraphy of the C a m b r i a n -
mentary, small trilobites, particularly agnostids and eodiscids.
Ordovician rocks in the Taconic allochthon. A d a p t e d from
Rasetti ( 1 9 4 6 , 1 9 5 2 , 1 9 6 6 a , b , 1967) with T h e o k r i t o f f ( 1 9 6 7 )
Landing ( 1 9 8 8 ) , with permission.
reported the following: LOWER
MIDDLE
GRANVILLE
Calodiscus lobotus
Elliptocephala
Fordaspis nana
Kootcnia
Serrodiscus
CAMBRIAN
Acidiscus
FORMATION
asaphoides
fordi
speciosus
birdi
Acimctopus Analox
Acidiscus
bilobatus obtusa
Bathydiscus
Analox Atops
dolichometopus
Bolboparia
hexacanthus bipunctata trilineatus elongata
Bolboparia
superba
Calodiscus
T h e dark shaly intervals with m o r e n u m e r o u s interbeds rep-
Calodiscus
fissifrons
Calodiscus
lobatus
agnostoides
resent a period of time either when the b o t t o m was m o r e stag-
Calodiscus
meeki
Calodiscus
occipitalis
THE
56
PALEOZOIC
GEOLOGY
OF
NEW
YORK
FIGURE 4 . 1 1 . Lower C a m b r i a n allochthonous b e d s of the low Taconic Mountains. Thin-striped white b e d s in the lower view are lime turbidites. A thin b e d of b r o k e n or b r e c c i a t e d limestone (a) o c c u r s (to the left of the h a m m e r ) . U p p e r b e d s are b l a c k shaly H a t c h Hill Formation ( b ) . Rte. 9 south of H u d s o n , C o l u m b i a County.
Calodiscus
reticulatus
Calodiscus
schucherti
Olenoidcs
Calodiscus
theokritofft
Calodiscus
walcotti
Pagetia
Chelediscus
chathamensis
Elliptoccphala
Eoagnostus
acrorhachis
Fordaspis
Hyolithellus
micans
"Kochiella"
Kootenia Oodiscus Pagetia
longispinus binodosus
bigra nulosa
Pagetides
amplifrons
fitchi
Seopagetina
punctulatus taconica
Oodiscus Pagetia
connexa
Pagetides
elegans
leiopygus
Pagetides
minutus
Pagetides
rupestris
Peronopsis
evansi
Rimouskia
cf.
P.
primigenea
Serrodiscus
speciosus
Serrodiscus
subclovatus
Stigmadiscus
Prozacanthoides Serrodiscus
typica
stenometopus
clytioides
Ptychagnostus
gibbus
Plethomctopus
knopfi
punctuosus
UPPER
Prosaukia
CAMBRIAN
briarcliffcnsis
subgranulatus
Pagetides Peronopsis
Ptychagnostus
Pagetia
nana
Leptochilodiscus
fordi
Litometopus
asaphoides
stockportensis erratica
Serrodiscus
Ordovician Period Unlike the C a m b r i a n , the Ordovician Period was a relatively long interval, s p a n n i n g about from 4 8 9 to 4 3 8 million years eatoni
griswoldi
ago. D u r i n g this long span, North America c o n t i n u e d to straddle the paleoequator, and New York lay in the southern subtropics
spinulosis
(Figure 4 . 5 ) . Early Ordovician saw a c o n t i n u a t i o n of the passive
Stigmadiscus
gibbosus
Great A m e r i c a n Tidal Flat e n v i r o n m e n t . But during the Middle
Weymouthia
nobilis
O r d o v i c i a n t i m e the eastern edge of Laurentia began to enc o u n t e r an offshore volcanic island arc ( c h a i n ) (Figure 4 . 1 2 ) .
MIDDLE
Ultimately this collision pushed (thrust) a great mass of deep-sea
CAMBRIAN
Baltagnostus
angustilobus
Baltagnostus
Bathyuriscus
eboracensis
Bolaspidella
Corynexochides?
expansus
Hypagnostus
stockportensis fisheri parvifrons
sediments up o n t o the present eastern edge of Laurentia, creating the Taconic M o u n t a i n s and causing the continental edge to collapse into a f o r e l a n d basin.
ORDOVICIAN
57
PERIOD
FIGURE 4.12. Stratigraphic chart of the O r d o v i c i a n e x p o s u r e s in N e w York.
M o d i f i e d from I s a c h s o n et al. (1991).
Printed with
permission of the New York State M u s e u m , Albany, N.Y
Early Ordovician
the C a n a d i a n Series. S o u t h of the Adirondacks, in the central M o h a w k River Valley, the Lower O r d o v i c i a n rocks are relatively
T h e Lower Ordovician interval in eastern N o r t h A m e r i c a is locally referred to as the Canadian Series (Figures 4 . 1 2 and 4 . 1 3 ) .
thin ( a b o u t 35 to 5 0 m ) a n d are assigned to a single f o r m a t i o n , the Tribes Hill (Figure 4 . 1 2 ) .
This interval, s o m e 20 million years in d u r a t i o n , is set o f f f r o m
T h e Lower O r d o v i c i a n ( C a n a d i a n ) Series rocks c r o p out in a
the higher Ordovician rocks in New York State and in most parts
roughly c o n c e n t r i c belt a r o u n d the A d i r o n d a c k region. To a large
of North America by the m a j o r K n o x U n c o n f o r m i t y , a 2 5 - to 30
extent, this o u t c r o p belt is controlled by the rather recent (late
million-year gap in the geological record. Moreover, the type of
C e n o z o i c ) uplift of the Adirondacks. However, it should be noted
sediments and the style of stratigraphy c h a n g e markedly between
that C a n a d i a n or Lower O r d o v i c i a n rocks are thin to absent in a
the Lower Ordovician and the late M i d d l e O r d o v i c i a n rocks that
belt r u n n i n g n o r t h w a r d f r o m Utica, New York, to an area north
overlie the unconformity. Lower O r d o v i c i a n rocks contain a
of Watertown.
sparse and rather poorly d o c u m e n t e d fossil fauna, d o m i n a t e d by
A m e r i c a was covered by shallow seas d u r i n g the Early O r d o v i -
certain small mollusks, such as various gastropods and nautiloid
cian, a low peninsular area of land extended eastward o f f the
cephalopods and rare trilobites. T h i s restricted Early O r d o v i c i a n
C a n a d i a n Shield roughly in the area of the T h o u s a n d Islands and
fauna suggests that somewhat unusual, perhaps slightly hyper-
Adirondacks of the present day. T h i s peninsula probably has
saline, conditions c o n t i n u e d in the N o r t h A m e r i c a n interior seas
n o t h i n g to do with the present expression of the Adirondacks. It
This
suggests
that
although
most
o f North
during this interval ot geologic time.
represents an a n c i e n t arch that was present in the c o n t i n e n t and
T h e Lower Ordovician strata
in New York generally are
probably developed during the t i m e of rifting of North America
assigned to the upper part of the B e e k m a n t o w n G r o u p that takes
f r o m a n o t h e r c o n t i n e n t in the late Proterozoic (late P r e c a m -
its name from an area near Lake C h a m p l a i n . In the o u t c r o p belt
brian). This
the Lower Ordovician rocks are best exposed and most c o m p l e t e
Ordovician c a r b o n a t e s thickened regularly to the south away
in areas around Lake C h a m p l a i n and southward to a b o u t Lake
f r o m this area. I s o p a c h m a p s ( m a p s showing variations in thick-
region
is referred to as the Frontenac Arch. T h e
formations,
ness of a particular rock unit) for the Lower Ordovician reveal a
each b o u n d e d by a m i n o r u n c o n f o r m i t y , are represented in
pattern c o m p a r a b l e to that seen in the C a m b r i a n in which the
George.
In
this
vicinity
at
least
four
distinct
FIGURE 4.13. New York d u r i n g the Early a n d early M i d d l e O r d o v i c i a n . A. Early O r d o v i c i a n , 495 million years before present. B. Early O r d o v i c i a n , 475 million years before present C. Cross section of plate m o v e m e n t d u r i n g the Early Ordovician s h o w i n g the Taconic Orogeny. D. C h a z y a n time. E. Black River times. F. Cross section of the plates d u r i n g the Middle O r d o v i c i a n . From I s a c h s o n et al. (1991). Printed with p e r m i s s i o n of the N e w York State M u s e u m , Albany, NY
FIGURE 4.13.
Continued.
THE
60
PALEOZOIC
GEOLOGY
OF
NEW
YORK
rocks thicken dramatically southward from the a p p r o x i m a t e zero
Ordovician were exposed to the a t m o s p h e r e for s o m e 25 to 30
line ( p i n c h - o u t of the Lower O r d o v i c i a n strata) that coincides
million years and b e c a m e deeply eroded. Because they had a
approximately with
relatively low siliciclastic c o n t e n t when exposed to rainwater, they
the
present
position
of the s o u t h
Lake
O n t a r i o shoreline. O r d o v i c i a n or C a n a d i a n age strata attain a
mainly underwent solution, although s o m e thin residues of sili-
thickness of nearly 1500 m in the subsurface near the New York
ciclastic m u d may have been developed on the karstic or solution
State-Pennsylvania b o r d e r and thicken still m o r e into central
surface. M a j o r solution features, such as sink holes and collapse
Pennsylvania, where they may exceed 3 0 0 0 m in thickness. T h e
b r e c c i a s , developed at this t i m e owing to karstification or disso-
rocks also thicken eastward from the area of the eastern A d i r o n -
lution and cave f o r m a t i o n and collapse of the older Ordovician
dacks into New England where they are represented as m e t a -
and C a m b r i a n c a r b o n a t e s . In places, the u n c o n f o r m a b l e surface
morphosed
has a relief of up to tens of meters.
carbonates
M a r b l e , about
1000m
(marble), thick.
including
North
the
o f the
Stockbridge
F r o n t e n a c Arch,
relatively thin sandy d o l o s t o n e s of the u p p e r m o s t Theresa and
Lower O r d o v i c i a n Strata and Trilobites
Ogdensburg f o r m a t i o n s represent the Lower O r d o v i c i a n c a r b o n -
T h e oldest o f the Lower Ordovician Canadian Series o f rocks
ates. T h e high sand c o n t e n t in these c a r b o n a t e s and in s o m e thin
are represented by the Whitehall F o r m a t i o n (Figures 4 . 1 2 and
intervals within the Lower O r d o v i c i a n of the M o h a w k Valley sug-
4 . 1 3 ) that is well exposed in the region n o r t h of Lake George near
gests that s o m e t e r r i g e n o u s sediment c o n t i n u e d to be swept f r o m
the town of Whitehall. T h i s f o r m a t i o n technically spans the
the now deeply weathered and eroding highlands of the F r o n -
C a m b r i a n - O r d o v i c i a n b o u n d a r y , but an upper unit within the
tenac Arch into adjacent shallow seas.
Whitehall appears to be set o f f by a m i n o r u n c o n f o r m i t y that
T h e upper units of the Lower O r d o v i c i a n , particularly the Fort
o c c u r s close to that b o u n d a r y . An erosion surface and overlying
Cassin F o r m a t i o n (Figures 4 . 1 2 a n d 4 . 1 3 ) , are restricted to areas
sandstone
east of the Adirondack M o u n t a i n s and the C h a m p l a i n Valley. No
appears to be a signature of a drop and initial rise in sea level.
and
siltstone
unit,
the
Winchell
Creek
Member,
trace of these units is f o u n d in the M o h a w k Valley farther west.
T h i s may represent a widespread regression that occurred near
T h i s suggests that toward the e n d of the Early O r d o v i c i a n ,
the end of the C a m b r i a n but still within the overall Sauk Super-
the area of deposition was restricted to a relatively narrow,
s e q u e n c e . T h e W i n c h e l l Creek Siltstone is overlain by somewhat
n o r t h - s o u t h trending basin lying close to the present eastern
fossiliferous limestone that has yielded occasional fragments of
New York State line and into New E n g l a n d . T h i s m a j o r change
trilobites as well as o t h e r m a r i n e fauna, suggesting partially
from widespread
normal marine conditions.
shallow seas over m u c h
of eastern
North
America to a n a r r o w eastern basin is n o t fully u n d e r s t o o d . In
T h e next higher and s o m e w h a t better-known interval, the
part, it may reflect m a j o r regression (shallowing or lowering of
Tribes Hill F o r m a t i o n (0 to 3 0 m ) , in the M o h a w k Valley, again
sea level) associated with the end of the Sauk S u p e r s e q u e n c e
c o m m e n c e s with a sandy or silty c a r b o n a t e in New York State, the
(Figure 4 . 1 3 B ) . A n o t h e r factor m a y b e tectonic d i s t u r b a n c e o f
Palatine Bridge M e m b e r . Again, this silt and sandstone unit over-
the eastern m a r g i n of N o r t h A m e r i c a . Such a d i s t u r b a n c e m a y
lies an u n c o n f o r m i t y that may represent an interval of m i n o r sea-
have produced a s u b s i d i n g ( d e e p e n i n g due to crust d e f o r m a t i o n )
level drop. T h e Palatine Bridge is overlain by b u r r o w - m o t t l e d and
trough in the region east of New York and New E n g l a n d , while at
s o m e w h a t fossiliferous W o l f Hollow M e m b e r that represents
the same t i m e the f o r m e r shelf area to the west was uplifted in a
shallow m a r i n e shelf deposition. T h e most fossiliferous unit
broadly upwarped archlike feature. It is notable that the Fort
within the Tribes Hill is the Fonda M e m b e r . T h e Fonda is a fossil-
Cassin F o r m a t i o n bears a n u m b e r of faults that are truncated by
rich limestone. S o m e beds display reddish to greenish c o l o r due
the overlying u n c o n f o r m i t y . T h e s e faults m u s t have o c c u r r e d
to the presence of iron mineralization, especially the clay mineral
following the deposition
glauconite. This latter mineral is believed to form in open marine
of the Fort
Cassin
Formation
but
before the deposition of the overlying M i d d l e O r d o v i c i a n strata.
e n v i r o n m e n t s during times of relative sediment starvation that
Evidently, the eastern edge of the c o n t i n e n t was u n d e r g o i n g s o m e
enables
stresses, perhaps associated with an initial e n c o u n t e r of eastern
decaying organic matter, especially fecal pellets. T h e glauconite
North A m e r i c a with a trench and the d e v e l o p m e n t of an offshore
granules of the Fonda M e m b e r are also associated with hashy,
volcanic island arc c o m p l e x . S o m e geologists have argued that
finely broken d o w n , skeletal remains of many types of organisms.
mineral
precipitate to b e c o m e concentrated
around
m i n o r volcanic ash input was already c o m i n g into the basin
Particularly prevalent are several species of small gastropods,
during the t i m e of the late C a n a d i a n E p o c h .
c e p h a l o p o d s , and a bivalve-like organism referred to as a ribeiroid
Early
Ordovician
deposition
was
terminated
throughout
rostroconch.
The
rostroconchs
represent
a
nonhinged
bivalve
eastern North A m e r i c a by a m a j o r fall in sea level, and an e r o -
mollusk that possibly was ancestral to the bivalves. T h e Fonda
sional u n c o n f o r m i t y , c o m m o n l y referred to as the Knox Uncon-
M e m b e r also contains rare, disarticulated fragments of trilobites.
formity,
middle
Finally the upper p o r t i o n of the Tribes Hill is represented
p o r t i o n of the O r d o v i c i a n , in places such as M o h a w k Valley, the
was
initiated
(Figure
again by stromatolitic dolostones assigned to the C h u c t u n u n d a
older c a r b o n a t e s that
C r e e k M e m b e r . T h i s unit c o n t a i n s large, but very poorly pre-
had
4.13A-D).
been
During
deposited
the
d u r i n g the
Early
ORDOVICIAN
PERIOD
61
served stromatolites referred to as " h i p p o b a c k s " where they c r o p
assigned to the Poulteney or D e e p Kill F o r m a t i o n (Figure 4 . 1 0 ) .
out, especially along C a n a j o h a r i e Creek, M o n t g o m e r y County.
Although p r e d o m i n a n t l y green, s o m e thin dark shale partings
T h e two higher packages of p r e d o m i n a n t l y d o l o m i t i c but
o c c u r within these strata, particularly in the vicinity of Deep Kill,
mollusk-containing carbonates, the Rochdale and the Fort Cassin
a small creek near Melrose, Rensselaer County. T h e s e Deep Kill
F o r m a t i o n , make up the remainder of the B e e k m a n t o w n G r o u p
black beds have yielded a highly diverse and well-preserved
of Lower Ordovician in New York (Figure 4 . 1 2 ) . T h e Fort Cassin
assemblage of graptoloid graptolites, typically preserved as silvery
shows a repeat of the same pattern observed in the lower units,
c a r b o n i z e d r e m n a n t s on the dark slaty bedding planes. T h e s e
particularly the Tribes Hill; that is, it c o m m e n c e s with a wide-
graptolites have been used to correlate the D e e p Kill rocks with
spread silt and sandstone unit, the Ward Siltstone M e m b e r , and
p o r t i o n s of the Lower O r d o v i c i a n in o t h e r parts of the world.
this in turn is overlain by a fossiliferous c o n d e n s e d limestone that
However, the bulk of the p r e d o m i n a n t l y green Poulteney or Deep
may record m a x i m u m m a r i n e flooding o f the c r a t o n o n a n o t h e r
Kill F o r m a t i o n is sparsely fossiliferous. In the Taconic allochthon
higher cycle. T h e upper part of the Fort Cassin, the B r i d p o r t
succession as on the c r a t o n , the Sauk U n c o n f o r m i t y or the Knox
Member, consists mostly of t h i n - b e d d e d to massive stromatolitic
U n c o n f o r m i t y appears to be present as a gap or break in sedi-
dolostones and records the final regression in the late part of the
m e n t a t i o n . Just why this should be so in deeper water is unclear.
Canadian Series. Brett and Westrop ( 1 9 9 6 ) recently reviewed
In fact, o n e might anticipate the o c c u r r e n c e of an increase in the
the trilobites from the Fort Cassin F o r m a t i o n .
influx of s e d i m e n t s , at least if shales were uplifted and exposed
Trilobites reported, in total, from the Lower O r d o v i c i a n are
to erosion d u r i n g the long span of the K n o x U n c o n f o r m i t y . However, the c o n t i n e n t a l slope and rise area of New England
as follows:
appear to have been relatively sediment starved during this interAcidiphorus
whittingtoni
Bathyurus
Bathyurus?
perkinsi
Bathyurellus
Bellefontia
gyracanthus
Bellefontia
Benthamaspis
striata
Clelandia
caudatus
Hystricurus Hystricurus
cf.
platypus
able volcanic ash beds that were being implaced within the
seelyi
world's oldest r a d i o l a r i a n - b a s e d , deep-sea silica o o z e deposits.
Iapetus O c e a n . Also, s o m e cherty beds represent s o m e of the
sp.
Hystricurus
H.
Hystricurus
T h e Poulteney is overlain, probably with an u n c o n f o r m i t y , by the
cassinensis
Grinnellaspis
conicus
val of t i m e . Siliceous layers within the Poulteney represent p r o b -
(?)
Bolbocephalus Eoharpes
parabola
Strigigenalis
levis
cf.
G.
marginiata
crotalifrons ellipticus
the east edge of Laurentia began u n d e r t h r u s t i n g the rest of
Isotcloidcs
canalis
Isoteloides
Isoteloidcs
whitfieldi
Paraplethopeltis
cf.
Shumardia
In the Early to M i d d l e O r d o v i c i a n , the Iapetus O c e a n no longer c o n t i n u e d to widen, and a p o r t i o n of seafloor attached to
oculilunatus
Robergiella
Indian River red slates. Trilobites are not present in these deposits.
R.
brevilingua
pusilla
Symphysurina
sp.
Symphysurus
convexus
peri
the seafloor (Figures 4 . 5 B and 4 . 1 3 C ) . T h i s a c t i o n produced a sp.
deep trench on the Iapetus O c e a n floor and a so-called sub-
Scotoharpes
cassinensis
duction zone, wherein the western plate or slab was forced d o w n -
Strigigenalis
cassinensis
ward beneath the eastern or overriding slab. T h i s interaction
Symphysurina
cf.
S.
woosteri
p r o d u c e d a n offshore island a r c — t h e Taconic o r A m m o n o o s u c Arc, a chain of volcanoes that f o r m e d on the overriding plate of p r o t o - A t l a n t i c seafloor. T h e m a g m a s (melted rock) were gener-
Allochthonous Rocks of Early Ordovician Age Lower Ordovician a l l o c h t h o n o u s rocks exposed in the western
ated by frictional heating and partial melting of the d o w n g o i n g slab and b r o k e through to the surface, f o r m i n g the volcanic chain.
part of the Taconic M o u n t a i n s closely resemble those of the
As s u b d u c t i o n of the p r o t o - A t l a n t i c seafloor c o n t i n u e d , the
Upper C a m b r i a n . Lowest Ordovician strata are represented by
eastern edge of Laurentia itself eventually was b r o u g h t close to
beds of the upper Hatch Hill F o r m a t i o n , as indicated by the pres-
the s u b d u c t i o n zone. Ultimately, the s e d i m e n t s that bordered
ence of distinctive index fossils including c o n o d o n t s . Graptolites
Laurentia along the c o n t i n e n t a l slope and deep o c e a n floor were
first b e c o m e c o m m o n in the strata of the Taconic M o u n t a i n s in
scraped o f f f r o m the d o w n g o i n g slab, f o r m i n g a s o m e w h a t c h a o t -
the earliest Ordovician, where they are represented by dendroid
ically d e f o r m e d series of slabs of s t r a t a — a n accretionary wedge.
graptolites such as the genus Dictyonema. Hatch Hill Shales, n o w
T h i s mass would b e c o m e the rocks of the T a c o n i c Allochthon (a
m e t a m o r p h o s e d in places to slates, c o n t i n u e upward from the
mass of rock ultimately displaced s o m e 80 km west of its site
Cambrian to the Ordovician. T h i n c a r b o n a t e s , sandstones, and
o f origin into the area o f present-day eastern New York). T h e
carbonate breccias, o c c u r r i n g at or near this level as well, repre-
Taconic a l l o c h t h o n was thrust or pushed up o n t o the c o n t i n e n -
sent sediments that were washed o f f the shallow p l a t f o r m of
tal shelf of Laurentia, or o n e m i g h t say that the east edge of the
North America at the end of the C a m b r i a n and earliest O r d o v i -
continental shelf was subducted beneath this mass of deformed
cian. T h e Hatch Hill dark shales give way upward in the strati-
sediments. T h e latter area also was being compressed and thrust
graphic succession to olive-greenish, slaty shales with s o m e thin
westward by collision of the A m m o n o o s u c Arc with the accre-
limestones but no debris flow breccias. T h e s e strata have been
tionary wedge and Laurentia.
THE
62
Middle Ordovician
PALEOZOIC
GEOLOGY
OF
T h e K n o x U n c o n f o r m i t y is manifested as the sharp upper units. T h e Knox U n c o n f o r m i t y , with a relief of up to several meters, due to karstification, is o n e of N o r t h America's m a j o r stratal breaks and f o r m s the subdivision
between two huge
packages of strata, referred to as Sloss supersequences: the Sauk Supersequence below and the base of the Creek phase of the T i p p e c a n o e Supersequence above (Sloss 1 9 6 3 ; Figure 4 . 1 ) .
o f trilobites: Acanthoparypha? Apianurus Bumastoides
(Basiliella)
gardenensis
Calyptaulax
annulata triacantheis granulosa
the Knox U n c o n f o r m i t y in New York are the sandstones and car-
Eobronteus Gabriceraurus
(Figure 4 . 1 3 D ) . T h e s e strata are o f middle M i d d l e Ordovician
Glaphurus
or Chazyan age (the Llandeilo Series of the British t e r m i n o l o g y )
Hemiarges
(Figures 4 . 1 3 D , 4 . 1 4 , 4 . 1 5 ) . T h e Chazy G r o u p strata evidently
Hibbertia Illaenus
Carrikia
globosus setoni
Ceraurinella
latipyga (Nieszkowskia)
Cyrtometopinid
dintoncnsis
bonates of the Lake C h a m p l a i n area, assigned to the Chazy G r o u p
comes
Bumastoides
Chcirurus
prima
Dinieropyge
accumulated in a relatively narrow, restricted trough or foreland
Bumastoides
aplatus
Bumastoides
Cybeloides
T h e oldest Middle O r d o v i c i a n strata to a c c u m u l a t e above
minganensis
Basilicas
whittingtoni
Ccratocephala
Middle O r d o v i c i a n C h a z y G r o u p
Amphilichas
sp. narrawayi
Ceraurus
hudsoni pustulosus turneri
amiculus
valcourensis crassicauda
antiquatus
Glaphurina
lamottensis
Heliotneroides Hibbertia Hyboaspis
depressa
Isotelus
angusticaudum
Isotelus Isotelus
and V e r m o n t . Laterally equivalent s e d i m e n t s of the Y o u n g m a n
Kawina?
and C a r m e n f o r m a t i o n s o f western V e r m o n t consist o f thin-
Kawina
bedded,
shales
Lonchodomas
halli
Nanillaenus?
that represent m o r e basinal a c c u m u l a t i o n s (Figure 4 . 1 3 D ) . T h e
Nanillaenus?
raymondi
Nieszko wskia
localized nature of the Chazy basin probably reflects additional
Nieszkowskia?
salyrus
Nileoides
subsidence o f the o u t e r p o r t i o n o f the continental margin o f
Otarion
Laurentia, w h i c h , d u r i n g the Middle O r d o v i c i a n , was b e g i n n i n g
Physemataspis
to e n c o u n t e r the trench or s u b d u c t i o n zone associated with the
Platillacnus
collision of a volcanic island arc.
Proetus
and
interbedded
dark
beta giganteus chazyensis vulcanus
spinicaudatum insularis limbatus
referred
to
as
the
Day
including lingulid b r a Point
Formation.
These
canalis
Isotelus
harrisi
Kawina?
sp.
Lonchodomas
chaziensis punctatus billi) lgs i perkinsi
Paraceraurus
ruedemanni
Platillacnus
erastusi
Pliomerops
canadensis
approximus Remopleurides
Pseudosphaerexochus
canadensis
vulcanus
siliciclastic sands apparently were recycled from older sandstones
Sphaercxochus
that had been e r o d e d d u r i n g the long span of the K n o x U n -
Thaleops
conformity. T h e y were deposited in shallow subtidal to inter-
Uromystrum
tidal e n v i r o n m e n t s . T h e overlying beds of the C r o w n
Vogdesia
Point
Isotelus
Pseudosphaerexochus?
clelandi
Chazy strata typically c o m m e n c e with c r o s s - b e d d e d sandstones c o n t a i n i n g sparse fossils, b u t
akacephala
sp.
o n c e extended farther to the n o r t h and east into central Q u e b e c
limestones
sp.
Eoharpes
sp.
mars
sp.
Dolichoharpes
basin that existed in present-day n o r t h e a s t e r n New York State and
chiopods,
YORK
trilobite fauna of the Chazy (Shaw 1968) includes over 60 species
contact o f the B e e k m a n t o w n G r o u p o r the underlying C a m b r i a n
ribbon-like
NEW
parvus
arctura brevispinum bearsi
Sphaerocoryphe Thaleops Uromystrum Vogdesia?
goodnovi
longispina minor obtusus
and Valcour in the Chazy G r o u p are c a r b o n a t e s that display generally deepening upward trends. C o a r s e - g r a i n e d limestones representing c r o s s - b e d d e d shoals of crinoidal and o t h e r skeletal
Middle Ordovician Allochthonous Rocks
debris occur low in the C r o w n Point F o r m a t i o n but are inter-
As previously m e n t i o n e d , the A m m o n o o s u c island arc, lay
bedded with and succeeded by n o d u l a r to wavy-bedded fine-
o u t b o a r d of N o r t h A m e r i c a in the proto-Atlantic in the region
grained limestones c o n t a i n i n g a b u n d a n t fossil fragments. Locally,
that today would be o c c u p i e d by central New England. T h e old
within
were
c r a t o n i c edge of Laurentia m a y have been uplifted to the east of
developed o n skeletal shoals (Figure 4 . 1 4 ) . T h e s e were c o m -
the Chazy trough. T h i s relatively narrow trough area lay to the
posed of sponges and b r y o z o a n s , with s o m e primitive rugose and
east, between the old continental margin (present-day central
tabulate corals. A small patch reef or b i o h e r m in a cow pasture
V e r m o n t and Massachusetts) and an accretionary prism, consist-
the
Crown
Point,
small
bioherms
or
reeflets
on Isle L a m o t t e , V e r m o n t , is often said to be the world's oldest
ing of the s e d i m e n t a r y rocks and s o m e o c e a n - f l o o r volcanics,
coral reef, although most of these b i o h e r m s were not c o m p o s e d
which were being o b d u c t e d o f f of the d o w n g o i n g o c e a n i c - f l o o r
o f corals.
plates (Figure 4 . 1 3 B , part E, F ) . T h e u p p e r m o s t or youngest sed-
Trilobites as disarticulated e l e m e n t s are rather c o m m o n and
iments of the Taconic a l l o c h t h o n succession accumulated in this
highly diverse in s o m e of the Chazy n o d u l a r limestone beds. T h e
trench during the Middle Ordovician and are approximately the
ORDOVICIAN
PERIOD
63
FIGURE 4 . 1 4 . Details of the stratigraphy of the Chazy Group in northeastern New York. From Shaw (1968), reproduced with permission.
same age as the Chazy carbonates of New York State. T h e s e strata
developed d u r i n g the l o n g - t e r m exposure of the craton during
belong to the Normanskill C r o u p and have been subdivided into
development of the K n o x U n c o n f o r m i t y . However, it also reflects
three m a j o r f o r m a t i o n s (Figure 4 . 1 0 ) . T h e lowest is a very dis-
a high degree of oxygenation of the b o t t o m waters during this
tinctive brick-red shale or slate referred to as the Indian River For-
t i m e . T h i s might be associated with the elevation of the seafloor
mation. This slate is exposed in m a n y places in the low Taconics
due to buckling and arching as the c o n t i n e n t edge of Laurentia
and has been quarried extensively tor roofing slates in the region
was driven into a t r e n c h .
of the New Y o r k - V e r m o n t border. T h e s e red slates lack b o d y
Overlying s e d i m e n t s o f the M o u n t M e r i n o F o r m a t i o n are
fossils but contain small trace fossils apparently m a d e by deep-
mostly dark gray or greenish gray siliceous shale. T h e y are also
sea burrowing organisms. T h e red coloration of the Indian River
noted for thin, r i b b o n - l i k e beds of distinctive light green cherts.
Slate is unusual and makes it particularly attractive as building
T h e s e cherts perhaps represent a c c u m u l a t i o n s o f radiolarian
stones. It reflects oxidized iron c o n c e n t r a t i o n within the m u d d y
(silicaceous microfossil)
sediments. However, the source of these iron e n r i c h m e n t s is still
seafloor. B o d y fossils are, again, extremely rare within the M o u n t
poorly understood. It might reflect highly weathered soil that
M e r i n o F o r m a t i o n . No trilobites are known.
skeletal
oozes on
the proto-Atlantic
THE
64
PALEOZOIC
GEOLOGY
OF
NEW
YORK
T h e highest and thickest p o r t i o n of the Normanskill G r o u p is
water intervals of the Black River deposition. T h e r e are no really
c o m p o s e d of the Austin Glen F o r m a t i o n ( c o m m o n l y referred to
g o o d m o d e r n analogs of such vast tidal flats with which to
as graywacke or m u d - r i c h s a n d s t o n e ) . In places, the Austin Glen
c o m p a r e the Black River depositional e n v i r o n m e n t s . Probably the
is enriched in small fragments of m e t a m o r p h i c rocks, including
closest would be s o m e of the extensive platform of the Bahama
slates
metamorphosed
Banks of today. Presumably, the Black River sediments a c c u m u -
c h u n k s o f the original proto-Atlantic seafloor s e d i m e n t s . T h e
lated in subtropical e n v i r o n m e n t s , approximately 25° south of
Austin Glen is noted for its thick sandstone deposits that are
the e q u a t o r (Figure 4 . 7 ) . However, s o m e workers have argued that
interpreted as t u r b i d i t e s , the product of deposition f r o m basin-
the overlying Trenton sediments may actually have developed
ward-flowing masses of suspended
under c o o l e r t e m p e r a t e rather than warm subtropical conditions.
that
probably
represent
uplifted
and
sediment and water that
moved due to gravity (Figure 4 . 1 5 ) . It is evident f r o m distinctive
Perhaps a climatic fluctuation did characterize the transition
flute and groove-casts on the undersides of m a n y of these thick
from the Black River to the Trenton.
turbidite beds that the sediment source now was f r o m the east,
T h e b r o a d , flat-shelf c o n d i t i o n s of the Black River deposition
probably o f f the erosion of the rising a c c r e t i o n a r y prism and vol-
indicate tectonic quiescence. However, the presence of thick b e n -
canic island arc. T h e s e rocks c o m p r i s e the highest p o r t i o n of the
t o n i t e s (volcanic ash beds) within the Black River strata indicates
Taconic strata, and they were thrust westward s o m e 80 km to their
that volcanism was o c c u r r i n g , perhaps in the A m m o n o o s u c Arc
present resting position, which approximates the position of the
at this t i m e .
modern Hudson River Valley. T h e Austin Glen does c o n t a i n o c c a -
T h e main b o d y of the Black River G r o u p consists of the
s i o n a l f o s s i l s i n places, including s o m e m a r i n e benthic fauna o f
Lowville F o r m a t i o n , also called Gull River F o r m a t i o n in O n t a r i o .
b r a c h i o p o d s , bryozoan scraps, and very rare trilobites.
T h i s is distinct, very pale gray weathering, massive micritic limestone. In past times it was c o m m o n l y referred to as the "bird's eye
Black River G r o u p
l i m e s t o n e " because of dark calcite spar-filled vugs. T h i s term
T h e rocks of the Chazy G r o u p in the C h a m p l a i n region are
originally referred to burrows of vertically excavating w o r m s ,
c o n f o r m a b l y overlain by a n o t h e r series of typically pale gray,
Phytopsis (Figure 4 . 1 6 ) . However, the term "bird's eye structure"
rather pure limestones referred to as a part of the Black River
has c o m e to refer to smaller vug- or pit-filling areas of dark calcite
G r o u p (Figures 4 . 1 3 E , 4 . 1 6 , a n d 4 . 1 7 A ) . T h e Black River G r o u p ,
also c o m m o n in the Lowville or Gull River F o r m a t i o n of the
n a m e d for exposures in the Black River Valley near W a t e r t o w n ,
Black River G r o u p . T h e s e are thought to represent originally
Jefferson C o u n t y , is a very widespread and distinctive package of
gas b u b b l e holes that developed from desiccation of c a r b o n a t e
shallow m a r i n e limestones that ranges up to 70 m thick (Figures
sediments in a tidal flat or perhaps from the decay of algal or
4 . 1 3 E , 4 . 1 6 , and 4 . 1 7 ) . Unlike the restricted Chazy, however, the
bacterial filaments within the sediments. Black River limestones
Black River limestones e x t e n d over most of central and western
contain
New York State and into the m i d c o n t i n e n t . In places, the Black
example, desiccation crack polygons are beautifully displayed on
evidence of extremely shallow-water deposition.
For
River c a r b o n a t e s rest directly on the K n o x U n c o n f o r m i t y and
m a n y bedding planes (Figure 4 . 1 6 A ) . Stromatolites also may be
c o m p r i s e the basal p o r t i o n of the Creek phase of the T i p p e c a n o e
c o m m o n locally, as are flat pebble conglomerates. T h e unit tends
Supersequence. In o t h e r areas to the northwest, the Black River
to be rather sparsely fossiliferous, although in places it contains
G r o u p rests directly on C a m b r i a n or even the Grenville (billion
spectacular, large nautiloid and e n d o c e r i d cephalopods. Scattered
year old)
unit,
trilobite fragments have been found within these rocks, but they
referred
basement to
as
rocks.
Pamelia
In these
Formation
in
regions, the basal
Shadow Lake
are not particularly c o m m o n or well preserved. Nonetheless,
F o r m a t i o n in O n t a r i o , consists of greenish gray to reddish m u d -
New York
or
the laterally equivalent Gull River Formation in O n t a r i o has
stones and sandstones, typically as p o o r l y sorted thin layers.
yielded beautifully articulated remains of the trilobite genus
W h e r e it rests on P r e c a m b r i a n b a s e m e n t , the S h a d o w Lake
Bathyurus
may incorporate cobbles o f quartzite o r other m e t a m o r p h i c
evidently ranged into relatively shallow water, as their remains
rocks. T h i s unit is n o r m a l l y unfossiliferous and is interpreted as
are associated with "bird's e y e " structures and other features
and
the
large
asaphid
Isotelus
sp.
These
trilobites
extremely shallow m a r i n e or n o n m a r i n e fluvial s e d i m e n t . H o w -
c o m m o n l y taken to indicate the upper subtidal to intertidal
ever, a few very scrappy r e m a i n s of fossils, including trilobites,
zone (Figure 4 . 1 6 B ) . Perhaps these represent carcasses that were
have been discovered from c a r b o n a t e beds in the S h a d o w Lake
stranded within the inner lagoon or tidal m u d flat e n v i r o n m e n t
F o r m a t i o n in O n t a r i o .
and buried intact.
T h e carbonates of the Black River G r o u p were deposited at a
Slightly darker gray limestones within the Black River G r o u p ,
t i m e when shallow, rather m o n o t o n o u s c o n d i t i o n s existed over
particularly near the top in what has been referred to as the House
very broad tracts of seafloor. Judging from the persistence of fea-
Creek and
tures, such as beds of m u d c r a c k s over h u n d r e d s of square miles
of the distinctive coral Tetradium, so called because of the four-
(Figure 4 . 1 6 A ) , it appears that vast areas were exposed and wetted
fold s y m m e t r y of its corallites and septa. T h e s e strata reflect
periodically by particularly high tides, at least d u r i n g shallow-
shallow-shell" lagoonal e n v i r o n m e n t s .
Watertown formations,
may contain
abundant
thickets
ORDOVICIAN
PERIOD
65
FIGURE 4.15. Flute casts on Austin Glen g r a y w a c k e ("dinosaur leather"). Basal surface of a vertically d i p p i n g b e d of M i d d l e O r d o v i c i a n sandstone turbidites shows sole marks i n c l u d i n g groove casts (a), ripple-like s c o u r s , a n d smaller flute casts (b). These features clearly indicate deposition from a turbidity current. A l l o c h t h o n o u s b e d s of low Taconics Austin Glen Formation. Cut in Rte. 9W near C o x a c k i e , G r e e n e County.
In a few locations, trilobites are f o u n d in the Lowville but
Basilicus ulrichi
Basilicus?
mostly in the upper or Watertown F o r m a t i o n (Young 1943a,
Basiliella barrandei
Bathyurus
1943b; D e M o t t 1 9 8 7 ) . T h e trilobites reported from the Black
Bathyurus johnsoni (Lowville)
Bumastoides
River are as follows':
vetustus extans
*Bumastoides milleri (Lowville)
Ceraurinella
Eoharpes pustulosus
b'ailleana
Illaenus latiaxiatiis
Isotelus
Isotelus simplex
Pterygometopus
tinguished by early authors. The trilobites with an asterisk may be early
Raymondites longispinus
*Raymonditcs
Trenton.
Thaleops ovata
The base of the Trenton and the top of the black River were not well dis-
(Lowville)
billingsi scofieldi indeterminata homalonotoides schmidti spiniger
FIGURE 4.16. Black River limestones. A. D e s i c c a t i o n c r a c k p o l y g o n s on the u p p e r surface of a b e d of fine-grained limestone. Lowville Formation, Black River G r o u p , East C a n a d a Creek near I n g h a m Mills in Fulton County. B. Beds of laminated limestone (intertidal environment) with vertical burrows (a) (Phytopsis). Note the s h a r p contact (b) with the dark gray limestone ( d e e p e r subtidal). East C a n a d a Creek at I n g h a m Mills in Fulton County.
FIGURE 4.17. M i d d l e O r d o v i c i a n Black River G r o u p . A. Overview of Black River G r o u p ( M i d d l e Ordovician) at East C a n a d a Creek, near I n g h a m Mills in Fulton County. Note the c h a n n e l in the u p p e r left a n d the sharp contact (arrow) of light gray vertically b u r r o w e d limestone over dark gray fossiliferous limestone. B. Sharp c o n t a c t (arrow) between the M i d d l e O r d o v i c i a n Watertown Limestone (Black River G r o u p ) a n d t h i n - b e d d e d N a p a n e e Limestone (Trenton G r o u p ) , Sugar River, Lewis County (north of Booneville, O n e i d a County).
G8
T H E
G E O L O G Y
O F
N E W
Y O R K
River erosion surface in m a n y localities, as the Napanee or A m s -
Trenton Group (General) A m o n g the most fossiliferous c a r b o n a t e rocks within the New York O r d o v i c i a n section are those o f the 3 0 - t o
P A L E O Z O I C
terdam F o r m a t i o n (Figure 4 . 1 2 ) .
130-m-thick
Trenton G r o u p (Figures 4 . 1 2 and 4 . 1 8 t o 4 . 2 3 ) . T h e Trenton rocks
Lower T r e n t o n G r o u p S h e l f Facies and Trilobites
record a m a j o r change f r o m shallow c a r b o n a t e shelf into a deep
T h e N a p a n e e F o r m a t i o n (Figure 4 . 1 8 ) ( 0 t o 1 0 m ) consists
foreland basin due to the thrusting of the T a c o n i c a l l o c t h o n .
o f t h i n - b e d d e d , b r o w n i s h c a r b o n a t e m u d s t o n e s o r calcisiltites
T h i s interval, which is classically exposed at Trenton Falls on West
interbedded with dark brownish gray shales that reflect a sig-
Canada Creek (Figures 4.21 to 4 . 2 3 ) , is a very widespread, highly
nificant increase in the a m o u n t of siliciclastic m u d input into
fossiliferous and c o m p l e x c a r b o n a t e succession.
the depositional system relative to the underlying clean car-
T h e lower portion of the Trenton rests sharply on the u n d e r -
b o n a t e s o f the Black River G r o u p . T h e Napanee carbonates
lying Black River G r o u p with an erosion surface that represents
are highly fossiliferous and are characterized particularly by
a regional u n c o n f o r m i t y . H e n c e , the base of the Trenton repre-
the b r a c h i o p o d Triplesia, but also a high diversity of other b r a -
sents a lesser s e q u e n c e b o u n d a r y within the T i p p e c a n o e Creek
c h i o p o d , b r y o z o a n , mollusk, and trilobite fossils. T h e s e beds
Supersequence (Figure 4 . 1 ) . Presumably, at the t e r m i n a t i o n of
are
Black River G r o u p deposition, seas were briefly withdrawn from
Flexicalymene
m u c h of eastern N o r t h A m e r i c a . However, the overlying Trenton
Napanee has been a source of debate. S o m e have argued that
strata appear to represent relatively deeper-water facies. All of the
the
Trenton G r o u p beds are highly fossiliferous.
lagoon system inboard of and protected by a c a r b o n a t e shoal.
some
of the
muddy
lowest
trilobites.
that
The
carbonates
contain
depositional
record
the
abundant
remains
environment
deposition
of a
of
of the shallow
Apparently, the t r a n s g r e s s i o n or deepening that began the
However, the widespread nature of these beds and the resem-
Trenton s e d i m e n t a t i o n was a strong or rapid o n e , of perhaps a
b l a n c e of their lithology and fauna to those of s o m e of the indis-
few tens of t h o u s a n d s of years, such that offshore l i m e m u d s and
putably deeper-water upper Trenton beds suggest a very different
silts were the first deposits that a c c u m u l a t e d above the top Black
interpretation.
FIGURE 4.18. C l o s e - u p of s h a r p Black River/Trenton ( W a t e r t o w n - N a p a n e e ) c o n t a c t . Note the massive limestone of the Watert o w n (a) a n d the thinly b e d d e d b r o w n limestone a n d shale of the N a p a n e e (b). East C a n a d a Creek near I n g h a m Mills in Fulton
ORDOVICIAN
PERIOD
69
T h e Napanee Limestone is abruptly overlain by a very thin interval
(0.5 m)
of beds
that
display a
shallow-water
River-like lithology with the return of Phytopsis and
Black
Tetradium
finds
Erratencrinurus
vigilans
and
Hemiargespaulianus,
two
trilo-
bites rarely f o u n d , if at all, in the higher units of the Trenton. Calyptaulax
callicephalus
occasionally
found
in
the
higher
rugose corals. These beds give way upward to the distinctive Kings
Trenton is c o m m o n in the Kings Falls. T h e trilobites notably
Falls Limestone, which contains a m i x t u r e of skeletal g r a i n s t o n e s
a b u n d a n t are s p e c i m e n s of Flexicalymene senaria and in the Sugar
that represent high-energy shoal e n v i r o n m e n t s and are c o m p o s e d
River
primarily
and
Cryptolithus lorettensis; the latter two fossils are considered to be
crinoids (Figure 4 . 1 8 ) . T h e grainstones are interbedded with
an index of the Sugar River ( S h o r e h a m i a n age). T h e y disappear
thinner-bedded limestones and dark gray shales that may repre-
f r o m the stratigraphic sections above the Sugar River in New
sent shallow, subtidal deposits that a c c u m u l a t e d o u t b o a r d from
York, but a related species reappears considerably higher, in the
the shoals. In turn, the Kings Falls c a r b o n a t e beds pass grada-
Lorraine G r o u p .
of
the
fragmentary
remains
of brachiopods
specimens
of the
trinucleids
Cryptolithus
tessellatus
and
tionally upward into the thicker Sugar River F o r m a t i o n ( 1 5 to
In the west, the upper Sugar River F o r m a t i o n includes a
25 m ) , which comprises, for the most part, wavy-bedded, rather
b u n d l e o f t h i n - b e d d e d micrites o r lutites ( f i n e - g r a i n e d , light
massive, slightly shaly wackestones and p a c k s t o n e s .
gray weathering l i m e s t o n e s ) , or R a t h b u n M e m b e r , that alternate
T h e Sugar River and Kings Falls units thin eastward to the
with dark gray shales capped by m o r e skeletal grainstones. T h e s e
vicinity of C a n a j o h a r i e , M o n t g o m e r y C o u n t y , where they are
seem to represent distal s t o r m deposits or lime m u d turbidites
locally pinched out near the crest of an apparent arch feature
that were a c c u m u l a t e d from shallower-shelf regions from the
on the Ordovician seafloor referred to as the Canajoharie Arch
n o r t h and west. T h e R a t h b u n appears to pass eastward into dark
(Figures 4.12 and 4 . 2 0 ) . A sharp discontinuity in this area sepa-
brownish gray shales in the vicinity of Little Falls, H e r k i m e r
rates the Sugar River, or Glen Falls L i m e s t o n e , the eastern New
C o u n t y . T h e y are typically rich in small, r a m o s e b r y o z o a n s and
York equivalent of the Sugar River, from the overlying dark gray
also m a y c a r r y a b u n d a n t trilobites of a n u m b e r of species, but
calcareous shales. T h e s e beds are particularly noted for their diverse assemblages of bryozoans, b r a c h i o p o d s , and trilobites. In the Kings Falls, o n e
particularly
dominated
by
Flexicalymene
sp.
Cryptolithus
lorettensis.
FIGURE 4 . 1 9 . C l o s e - u p of storm b e d s in the Middle Ordovician Kings Falls Limestone (Trenton Group). Note the c h a n n e l e d b a s e of b e d (arrow) midway up the h a m m e r handle. East C a n a d a C r e e k near Ingham Mills in Fulton County.
tes-
sellatus is mostly replaced in the R a t h b u n by a variant called C.
FIGURE 4 . 2 0 . M a p s of New York d u r i n g late M i d d l e O r d o v i c i a n times. A. Kirkfieldian d u r i n g deposition of the lower Trenton. B. S h e r m a n i a n d u r i n g the d e p o s i t i o n of the m i d d l e Trenton. From Isachson et al. (1991). Printed with permission of the N e w York State M u s e u m , Albany, N.Y
ORDOVICIAN
71
PERIOD
Trilobites of the lower T r e n t o n , up through the Sugar River are as follows:
C o m m o n l y the beds display a basal surface that may be overlain by a thin (millimeters thick) layer of shell and trilobite hash. U p p e r parts of the beds m a y be laminated but typically show disruptions due to b u r r o w i n g . C o n t a c t s with the overlying c h o c o -
Amphilichas
trentonensis
Bathyuropsis
schucherti
Bumastoides
porrectus
Bumastoides
trentonensis
late-brown shales may also display well-preserved fossils, such as
callicephalas
Calyptaulax
eboraceous
articulated
pleurexanthemus
Cryptolithus
lorettensis
ticularly c o m m o n in beds of the Poland near Trenton Falls. Large
C.
s p e c i m e n s of Isotelus gigas are also locally a b u n d a n t , and a bed
Calyptaulax Ceraurus Cryptolithus
tesscllaius
Cyphoproetus
cf.
Encrinuroides
cybeleformis
Encrinuroides
Eomonorachus
convexus
Erratencrinurus
Flexicalymene
senaria
Gabriceraurus
Gravicalymene
Hemiarges
wilsonae
/.
Isotelus
gigas
Isotelus
latus
near the top of the Poland at Trenton Falls apparently yielded the
vigilans
m a j o r i t y of the well-preserved, black, articulated I. gigas specim e n s that are f o u n d in m u s e u m s a r o u n d the world. T h i s is a
dentatus
relatively coarse bed of skeletal debris, a p p r o x i m a t e l y 30 cm thick,
paulianus
Illaenus Isotelus
served, mostly inverted, on the base of this b e d . T h e s e evidently
latidorsatus
represent o r g a n i s m s that were caught up and buried in a graded
jacobus
Plaiylichas ingalli
Triarthrus
is par-
which fine upward into c a r b o n a t e silt and trilobites were pre-
conradi
Raymondites
T h e trilobite Flexicalymene senaria
trentonensis
magnotuberculata Illaenus cf.
trilobites.
debris bed deposited by s t o r m waves.
inconsuetus
Sceptaspis
bebryx
Various features of the Poland beds strongly suggest that they
beckii
represent s t o r m - d e p o s i t e d c a r b o n a t e s t r a n s p o r t e d to offshore, n o r m a l l y quiet water e n v i r o n m e n t s . A relatively diverse fauna
M i d d l e and Upper T r e n t o n G r o u p
o c c u r s in these beds. In addition to trilobites, varied b r a c h i -
T h e middle p o r t i o n of the Trenton has been referred to as the Denley or Denmark Formation ( 1 9 3 7 , 1943,
(Figures 4 . 2 1
and 4 . 2 2 ) .
Kay
o p o d s and b r y o z o a n s , especially small s p e c i m e n s of Prasopora, are a b u n d a n t within s o m e layers in the Poland. F o r a listing of
1968) subdivided the middle Trenton into two
the trilobites of the Denley F o r m a t i o n , see the publications by
m e m b e r s : the Poland and the Russia, b o t h defined in the T r e n t o n
Titus ( 1 9 8 2 , 1 9 8 6 ) and D e l o ( 1 9 3 4 ) for discussions o f the trilo-
Falls area. M o r e recently, the middle Trenton units of the Poland
bites and their c o m m u n i t i e s .
and Russia M e m b e r s were grouped into the D e n l e y L i m e s t o n e . T h e s e units
Toward the top of the Poland interval occurs a series of thin
represent a transition f r o m d e e p - s h e l f to m o r e
b e n t o n i t e beds. W e a t h e r i n g o f these beds typically f o r m s n o t c h e s
shallow-shelf encrinal limestones. T h e y pass eastward in dark
in o u t c r o p s , such as those seen near the top of the classic
gray and black shales, the Flat C r e e k F o r m a t i o n , that signify c o l -
S h e r m a n Falls section at Trenton Falls, H e r k i m e r C o u n t y (Figure
lapse of the eastern Laurentia shelf area into a foreland basin as
4 . 2 2 ) . T h e top of the Poland is b o u n d e d by a distinctive wide-
the Taconic O r o g e n y set in.
spread interval including two key b e n t o n i t e s . T h e s e two beds,
In the area around Middleville, H e r k i m e r C o u n t y (in par-
separated by 0 . 5 - to 1-m n o d u l a r l i m e s t o n e , f o r m the base of the
ticular, outcrops on City B r o o k ) , the thin beds of the R a t h b u n
Russia M e m b e r (Figure 4 . 2 3 ) . T h e Russia, overall a b o u t 2 3 m
Member
fossiliferous
thick, is divisible into a series of small-scale coarsening upward
limestone about 1 m thick that marks the base of the Denley
cycles. Each cycle c o m m e n c e s with dark shale and thin tabular,
F o r m a t i o n . T h i s interval, the " C i t y B r o o k b e d " o f the Poland
very-fine-grained micritic limestones similar to those seen in
M e m b e r , is exceptionally rich in fossil nautiloid and e n d o c e r i d -
parts o f the Poland. T h e tops o f these cycles are c o m p o s e d o f
cephalopods. T h e City B r o o k bed carries the distinctive coiled
m o r e thickly bedded, nodular, fossil-rich l i m e s t o n e . A particu-
nautiloid
are
capped
Trocholites
by
nodular,
larly distinctive package of fine, evenly b e d d e d , light gray weath-
particularly
ering limestones o c c u r s near the top of the Russia in areas around
c o m m o n . T h i s interval is also rich in the remains of Flexicalymene,
Trenton Falls (Figure 4 . 2 3 ) . Like the Poland, the Russia M e m b e r
mostly disarticulated, but s o m e of which are preserved as enrolled
yields a b u n d a n t and c o m m o n l y well-preserved fossils. Certain
individuals. T h i s c e p h a l o p o d - and trilobite-rich bed is considered
bedding planes again display completely articulated trilobites
to represent a condensed h o r i z o n , that is, a b e d that records a
and crinoids, indicating very rapid pulses of burial. As with the
considerable a m o u n t of t i m e in a relatively thin interval. Such
P o l a n d , it is t h o u g h t that m a n y of these thin limestones repre-
cephalopod beds are typical of times of relatively rapid deepen-
sent distal w a s h o f f of c a r b o n a t e silt sands and m u d s following
ing when siliciclastic sediments appear to b e c o m e trapped in
times when s t o r m s disrupted the shallow shelf. S t o r m s resus-
nearshore areas and carbonates are not produced at a high rate.
pended finer c a r b o n a t e silts and m u d s and incorporated them
although
was
distinctive
the
Trocholites bed,
and
a
the
previously latter
fossil
referred is
not
to
as
T h e remainder o f the Poland M e m b e r consists o f thin- t o
into basin-flowing g r a d i e n t c u r r e n t s . T h e s e currents carried the
m e d i u m - b e d d e d , fine-grained limestones with c h o c o l a t e - b r o w n
sediments d o w n a gently sloping shelf or r a m p to the southeast.
shale partings (Figure 4 . 2 2 ) . M a n y of the limestones are rather
Nodular beds within the Russia represent s o m e w h a t shallower
fossiliferous and c o m p o s e d mainly of c a r b o n a t e silt (calcisiltite).
water e n v i r o n m e n t s that were disturbed b o t h by w i n n o w i n g
FIGURE 4 . 2 1 . M i d d l e Trenton at Trenton Falls. A. C o n t a c t of the Poland (a) a n d Russia (b) M e m b e r s of the Denley Formation ( M i d d l e O r d o v i c i a n Trenton G r o u p ) , m a r k e d by a d e e p re-entrant (arrow at b a s e of s h a d o w ) of Kayahoora bentonite b e d s . West C a n a d a Creek a b o v e S h e r m a n Falls, Trenton Falls, O n e i d a County. B. Overview of the M i d d l e O r d o v i c i a n Trenton G r o u p , s h o w i n g the Russia M e m b e r (a) of the Denley Formation a n d the Rust Formation (b). U p p e r H i g h Falls, Trenton Falls on West C a n a d a Creek, O n e i d a County.
ORDOVICIAN
73
PERIOD
FIGURE 4.22. M i d d l e O r d o v i c i a n Trenton G r o u p limestone (mainly Poland M e m b e r of the Denley Formation) at S h e r m a n Falls, West C a n a d a Creek, Trenton Falls, O n e i d a County. Note the d e e p l y r e c e s s e d n o t c h e s (arrow) m a r k i n g the positions of bentonites (volcanic ash b e d s ) near the t o p of the falls.
currents and by b u r r o w i n g o r g a n i s m s that flourished in the
Ash
somewhat better-oxygenated shelf e n v i r o n m e n t s . T h e sediment
the base of a thin shaly interval at the b o t t o m of the Rust
(Figure
4.23A).
This
critical
marker
bed
occurs
at
shutoff associated with the t o p s of t h e cycles allowed develop-
Formation.
m e n t of s o m e thin skeletal hash limestone deposits that capped
Approximately 17 m above the base of the Rust is an interval
the cycles. Abrupt deepening above these caps is recorded by
up to 3 m thick in which the beds are heavily c o n t o r t e d and
a
d e f o r m e d (Figure 4 . 2 3 B ) . In places, individual beds appear to
shift
back
to
dark
shales
and
then
to
very-fine-grained
limestones.
have b e e n o v e r t u r n e d u p o n o n e a n o t h e r and doubled along
Overlying the Denley F o r m a t i o n , near Trenton Falls, is the Rust
F o r m a t i o n , approximately 30 m of rather nodular, fos-
r e c u m b e n t folds. In o t h e r areas such as near the spillway of the power d a m
within Trenton G o r g e , these d e f o r m e d
intervals
siliferous, poorly bedded, t h i n - b e d d e d limestone (Figure 4 . 2 3 ) .
appear to be confined to lenticular channel-like features. T h e s e
T h e Rust
begins abruptly with a very distinctive b e n t o n i t e
beds record an interval of s l u m p i n g of sediment on the Trenton
bed exposed in the upper High Falls of the Trenton G o r g e on West
seafloor that may have b e e n the result of tectonic steepening
Canada Creek in H e r k i m e r C o u n t y , referred to as the High Falls
o f the c a r b o n a t e r a m p . T h i s d e f o r m a t i o n together with the
FIGURE 4.23. Trenton at Trenton Falls. A. View of U p p e r H i g h Falls s h o w i n g c o n t a c t of the t h i n - b e d d e d , light gray w e a t h e r i n g Russia Member, Denley Formation (a), overlain by the darker Rust Formation (b). C o n t a c t is m a r k e d by a re-entrant (arrow) at the position of the H i g h Falls bentonite. Trenton Falls on West C a n a d a Creek, O n e i d a County. B. C o n t o r t e d b e d s (a) in the m i d d l e portion of the Rust Formation. Thin b e d s near the b a s e (b) are the Walcott-Rust Quarry b e d s . Spillway at the p o w e r d a m within the Trenton Falls G o r g e , Herkimer County.
ORDOVICIAN
PERIOD
7b
abundant thin bentonite (or volcanic ash) layers in the D e n l e y -
fine structure of appendages was well preserved by very early
Rust interval signals the onset of m a j o r tectonic activity in the
calcite infilling. T h e s e fossils were the first trilobites for which
Taconic belt east of the present Hudson River Valley. T h e s e
appendage structure was carefully analyzed and d o c u m e n t e d
channel-like
features are still
poorly u n d e r s t o o d
but
might
(Walcott 1 8 7 5 a , b , c , d ) . T h i s s a m e bed yielded abundant speci-
represent m i n o r bypass channels eroded into the underlying c a r -
m e n s of C. pleurexanthemus, m o s t (at least 9 5 % ) in an inverted
bonate muds and then infilled with n o d u l a r shaly limestones,
position, along the lower surface and in c o n t a c t with the brown-
which in turn were slumped during a t i m e of tectonic distur-
ish gray interbedded shale. T h i s parting also has produced nearly
bance.
c o m p l e t e crinoids
There
is
no
doubt
that
this
slumping
deformation
( w i t h o u t the holdfasts)
and several other
occurred in relatively soft, wet sediments on the seafloor. T h e
species of whole trilobites. T h e q u a r r y limestone beds appear to
upturned edges of the folded beds in the middle part of the
represent distal deposits of s e d i m e n t s that were resuspended,
Rust are truncated by an erosion surface and overlapped by a bed
probably during s t o r m s in shallower water areas, and imported
of crinoidal grainstones that c o n t a i n s a breccia of pebbles derived
onto
from the underlying d e f o r m e d beds. T h e highest beds of the
Typical c o n d i t i o n s in this area were low-energy, soft, muddy
a
southeastward-sloping c a r b o n a t e
ramp
environment.
Rust Formation are t h i n - b e d d e d , coarser-grained crinoidal lime-
substrate settings that s e e m e d to favor a variety of delicate
stones that appear to b e c o m e s o m e w h a t thicker and coarser
b r y o z o a n s , c r i n o i d s , cystoids, and at least 21 reported species of
upward, perhaps in transition to the overlying massive crinoidal
trilobites, including the following:
grainstones of the Steuben F o r m a t i o n . T h e Rust limestones c o n t a i n very a b u n d a n t trilobite and
Achatella
achates
Amphilichas
crinoid debris, bryozoans, b r a c h i o p o d s , and particularly n a u -
Amphilichas
tiloid cephalopods. T h e beds tend to be rather poorly defined
Bumastoides
and c o m m o n l y s o m e w h a t a m a l g a m a t e d (bundled together) in
Bumastoides
porrectus
Calyptaulax
the lower portion of the Rust.
Calyptaulax
eboraceous
Ceraurus
A package of t h i n - b e d d e d
limestones referred to as
cornutus
conifrons
Amphilichas
decemsegmentus
inaequalis
Bumastoides
holei callicephalus pleurexanthemus
the
Diacanthaspis
parvula
Flexicalymene
VValcott-Rust Q u a r r y beds, o c c u r r i n g a b o u t 12 m above the base
Gabriceraurus
dentatus
Gerasaphus
of the Rust F o r m a t i o n s , has yielded exquisitely preserved fossils
Hypodicranotus
(Figure 4 . 2 3 B ) . T h i s t h i n - b e d d e d and rather fine-grained inter-
Isotelus
val in the Rust F o r m a t i o n sharply overlies burrowed fossiliferous
Nanillaenus
limestone that caps a shallowing cycle within the lower Rust.
Sphaerocoryphe
striatulus
Isotelus
walcotti
senaria ulrichiana
gigas
Meadowtownella
americanus
trentonensis
Proetid sp.
robusta
T h e presence of m o r e distal, deeper-water facies suggests that this interval represents a time of m i n o r deepening within the basin
T h e strata above the q u a r r y beds interval including the upper dis-
due to either tectonics or sea-level rise. T h e W a l c o t t - R u s t Q u a r r y
turbed zone c o m p r i s e t h i n - b e d d e d , very nodular, shaly fossili-
beds interval exposed near the f o r m e r Rust farm estate was dis-
m e n i d ferous wackestones and packstones that are particularly
covered and initially excavated by Charles Walcott. Collections
rich
from this site were sold to the M u s e u m of C o m p a r a t i v e Z o o l o g y
Platystrophia. Nautiloids are also c o m m o n , but trilobites are less
at Harvard in the 1870s and were listed in a paper by Delo ( 1 9 3 4 ) .
a b u n d a n t than below and are typically fragmentary. T h e s e beds
in
strophomenid
brachiopods
such
as
Rafinesquina
and
T h e Walcott-Rust Q u a r r y beds consist of sharply based a n d , in
record heavily b u r r o w e d sediments deposited in shallow, s t o r m -
s o m e cases, graded layers of fossil debris and c a r b o n a t e silt or
wave influenced e n v i r o n m e n t s .
m u d . Fossils o c c u r both on bedding planes and within s o m e of
T h e Rust grades up into the Steuben L i m e s t o n e , a heavy
the very-fine-grained beds. Remains of these o r g a n i s m s were
bedded
caught up within the turbid flows that carried the c a r b o n a t e
w i n n o w e d c r i n o i d remains and indicates a p e r i o d of shallow
m u d . Carcasses or living o r g a n i s m s may have been transported
water above wave-base. Although trilobites have been reported
crinoidal
grainstone.
The
Steuben
is
composed
of
a short distance locally before being deposited and very rapidly
from the c o m p r e s s e d shale between the beds of the S t e u b e n , they
covered by the settling c a r b o n a t e m u d s .
are u n c o m m o n .
However, in s o m e
instances, organism remains were buried exactly in situ as evidenced by upright cystoids and b r y o z o a n s encased within a l i m e -
In
the
Poland,
H e r k i m e r C o u n t y , area the entire
upper
Trenton also appears to u n d e r g o a rapid t h i n n i n g and passage
stone bed. Most of the carbonates represent individual c a r b o n a t e
into gray shales and calcilutites to the southeast. T h e Rust beds
event beds, either gradient current deposits or turbidites that fol-
and the underlying Russia are b o t h very c o n d e n s e d and thin
lowed turbulent scouring and resuspension in upslope areas. T h e
in the vicinity of Middleville,
original quarry site was re-excavated and the layers e x a m i n e d for
entire Rust M e m b e r , over 27 m at Trenton Falls, is thinned to just
trilobites in s o m e recent work (Brett et al. 1 9 9 9 ) . In particular, a
under 2 m.
bed at the base of the quarried interval yielded a series of partially enrolled F.
senaria and C. pleurexanthemus, in which
the
H e r k i m e r C o u n t y , where the
North and west of the M o h a w k Valley, the Hillier Limestone overlies the Steuben L i m e s t o n e in a generally deepening upward
76
THE
PALEOZOIC
GEOLOGY
OF
NEW
YORK
progression. T h e Hillier consists of shaly, nodular limestone with
upward with a series of thin ash beds into the overlying Dolgeville
abundant
Formation.
cephalopods
and
a
few
Flexicalymene specimens.
Lag
deposits between the Hillier and the overlying black shales ( D e e r
To the east, in the Hudson Valley area, the black Flat Creek or
River F o r m a t i o n ) with bored p h o s p h a t e pebbles c o n t a i n the trilo-
C a n a j o h a r i e shales grade into a thick succession (over 5 0 0 m ) of
bites
dark gray shales and turbidite sandstones referred to as the Snake
Ceraurus
sp.,
Flexicalymene
sp.,
and
Pseudogygites
latimar-
ginatus. T h e latter, a c o m m o n trilobite from the equivalent beds
Hill
in O n t a r i o , is only k n o w n f r o m the Hillier and the base of the
rapidly in a trough that lay just west ( m o d e r n directions) of the
Deer River in New York.
Formation
(Figure
4.20B).
These
sediments
accumulated
rising Taconic thrust mass. T h i s is evident not only because the
Trilobites are c o m m o n and diverse in the upper Trenton strata
thrust sheets lie o n , or in, the Snake Hill Shale, but also because
from Middleville northwest into O n t a r i o . W i t h i n the Trenton
the Snake Hill includes pebbles and even huge blocks of rocks
above the Sugar River are f o u n d the following:
derived from the old shelf edge to the east. T h e s e include limestone blocks that c o n t a i n disarticulated trilobite parts, evidently
Achatella
achates
Amphilichas
cornutus
Bumastoidcs
decemsegmcntus
Bumastoides Calyptaulax Ceraurus
inaequalis
lapsed as debris flows into the Snake Hill Shales.
Bumastoidcs
eboraceous
Ceraurinus
vigilans dentatus
Gravicalymene
magnotuberculata
gigas
Kawina
" b u l l d o z e d " by the i n c o m i n g Taconic thrust sheets and then col-
Amphilichas Calyptaulax
Erratenerinurus
Isotelus
conifrons
porrectus pleurcxanthemus
Gabriceraurus
Amphilichas
T h e eastern equivalent of the highest Trenton beds is a very
callicephalus marginal us
Little
Falls
exit,
called
the
Dolgeville
F o r m a t i o n . Dolgeville consists o f thin ( 5 t o 2 0 m m ) platy beds o f very-fine-grained limestone alternating with black shale (Figure
ulrichiana
4 . 2 4 A ) . T h e black and light bed striping are a very striking m o t i f
Gerasaphus Hypodicranotus
striatulus
walcotti
Lonchodomas
Proetid sp.
Pseudogygites Triarthrus
in weathered o u t c r o p s . T h e thin limestones are believed to be turbidites of l i m e m u d washed o f f the shallow platform (Rust to Steuben depositional area) to the west. T h e shaly intervals of the Dolgeville
americanus
contain
Triarthrus
beckii.
T h e top of the Dolgeville beds shows deformation presumably due to s l u m p i n g on the seatloor prior to deposition of the over-
latimarginatus Triarthrus
the
senaria
Nanillaenus
robusta
near
parvula
Meadowtownella trentonensis
Sphaerocoryphe
Thruway,
Flexicalymene
hastatus
Irenlonensis
distinctive rock unit, well exposed along the New York State
Diacanthaspis
Isotelus (Pseudosphaerexochus)
holei
bcckii
lying black shale. All of this suggests strong tectonic influence of the T a c o n i c O r o g e n y in the foreland basin at this time (Figures 4 . 2 0 B and 4 . 2 5 ) . T h e Dolgeville F o r m a t i o n and Steuben Lime-
catoni
stone are abruptly overlain by black shales of the Indian Castle Eastern T r e n t o n Equivalents a n d Utica Shale T h e eastward fate o f the upper p o r t i o n s o f the Trenton G r o u p remains s o m e w h a t u n c e r t a i n , pending correlation o f b e n t o n i t e
( U t i c a ) F o r m a t i o n (Figure 4 . 2 4 B ) . T h i s implies abrupt deepening over m u c h of New York State due to an episode of tectonic Subsidence.
beds within the section. T h e Poland and Russia M e m b e r s appear
On the basis of the m e t a b e n t o n i t e s and graptolites, it can be
to undergo a transition into p r e d o m i n a n t l y dark gray to black
shown that the Indian Castle Shale is a westwardly thinning
platy shales in the vicinity of Caroga Creek, Fulton C o u n t y , and
wedge of rock with progressively higher units onlapping the
St. Johnsville, M o n t g o m e r y C o u n t y . However, p o r t i o n s of the
Trenton U n c o n f o r m i t y in a westwardly direction. T h e s e black
Rust appear to e x t e n d eastward as a calcareous z o n e , " t h e W i n -
shale beds appear c o n f o r m a b l e with the underlying Dolgeville
tergreen Flats b e d s " that c a r r y Prasopora and c a l y m e n i d trilobite
in eastern M o h a w k Valley. Finally, near Middleville, H e r k i m e r
material at least as far east as Flat C r e e k near Sprakers, M o n t -
Count}', black shales of the u p p e r Utica b e d s rest with sharp dis-
g o m e r y County. D a r k Flat C r e e k ( C a n a j o h a r i e ) Shales, p a r t i c u -
c o n f o r m a b l e c o n t a c t on a c o r r o s i o n surface in the upper Steuben
larly those overlying the W i n t e r g r e e n Flats Prasopora b e d , contain
Limestone.
an a b u n d a n c e of the trilobite
Triarthrus beckii. T h e shales also
T h e dark Flat Creek and Snake Hill shales that are laterally
b e c o m e quite rich in graptolite fossils that are dated as near the
equivalent to the upper Trenton are sparsely fossiliferous and rep-
top of the Corynoides americanus graptolite zone. A dark gray or
resent deeper-water e n v i r o n m e n t s with high rates of sediment
black shale bed overlies the W i n t e r g r e e n beds in the vicinity of
accumulation.
C a n a j o h a r i e and appears to represent a m a j o r deepening within
sparingly.
Graptolites and
Triarthrus specimens are found
the section. T h i s interval may c o i n c i d e with the W a l c o t t - R u s t
In the H u d s o n Valley the Snake Hill Shale also contains debris
Q u a r r y beds in the Trenton Falls area. It is the zone that carries
flows and b l o c k s of exotic material that were thrust in from the
the m o s t a b u n d a n t Triarthrus beckii in the central and eastern
eastern area. O n e such mass is the Rysedorph C o n g l o m e r a t e .
M o h a w k Valley region. T h i s dark gray shale, newly t e r m e d the
Two miles southeast of Rensselaer, New York, Rysedorph Hill
"Valley B r o o k S h a l e " (Brett and Baird, in press), appears to pass
is underlain by an unusual c o n g l o m e r a t e , the Rysedorph C o n -
FIGURE 4 . 2 4 . Middle Ordovician Dolgeville and Utica rocks. A. Middle Ordovician Dolgeville Formation sharply overlain by Indian Castle (Utica Group) black shale (upper white arrow at the contact). Note the thin "ribbon limestones" and black shale, and the small folds (lower white arrow) in the Dolgeville beds. New York State Thruway, 1.6km (1 mile) west of the Little Falls exit, Herkimer County. B. Black Indian Castle (Utica Group) shale, with light weathering limestone beds. East Canada Creek, Dolgeville, Herkimer County.
78
THE
PALEOZOIC
GEOLOGY
OF
NEW
YORK
g l o m e r a t e . Various pebbles within this unit c o n t a i n fossils f r o m
center of the Utica trough, which extended eastward toward New
C a m b r i a n t o U p p e r O r d o v i c i a n . S o m e o f the M i d d l e Ordovician
England.
trilobites o b t a i n e d by R u e d e m a n n ( 1 9 0 1 ) are n o t f o u n d elsewhere in New York, but s o m e are k n o w n in Virginia. M o s t of
Lorraine Group
these remains are fragmentary, and the actual species assign-
Strata of the late p o r t i o n of the Ordovician Period in New
m e n t s may not be correct in all cases. T h e trilobites include the
York State reflect the filling and overfilling of the Taconic fore-
following:
land basin. In eastern and east-central New York State these strata above the Schenectady F o r m a t i o n have been removed by a s u b -
Achatella
achates
Calyptaalax
callicephalus
Ceraurus Cybele
Calyptaulax Ceraurus
pleurexanthemus
Isotelus
ulrichiana
Lonchodomas Otarion? Thaleops
Tretaspis
ovata
Tretaspis
the F r a n k f o r t ) , and Pulaski
americanus
m e m b e r s , and the Oswego and
Q u e e n s t o n f o r m a t i o n s (Figures 4 . 1 2 and 4 . 2 5 ) . T h e Frankfort-
linguatus
Sphaerocoryphe
tumidus
G r o u p with its Frankfort, W h e t s t o n e G u l f (western equivalent of
maximus
Remopleurides
matutinum
Remopleurides
filling phases of the Taconic Basin are recorded in the Lorraine
senaria
Nanillaenus
hastatus
M o h a w k Valley region and northwestern New York State, the
lunatus
Flexicalymene
Gerasaphus
Silurian and Early Devonian deposits. However, in the western
sp.
Eobronteus
sp.
sequent period of uplift and erosion prior to onlapping of
eboraceous
Pulaski succession c o m m e n c e s with dark gray shales and shows
major
a general c o a r s e n i n g - u p w a r d trend through siltstones and sand-
reticulata
stones. Parallel with this is a change from anoxic to fully oxy-
diademata
genated seafloor c o n d i t i o n s reflected in increasingly diverse fossil assemblages. Overall, the seafloor was shallower due to fill-in or
Late Ordovician
p r o g r a d a t i o n of the sediments from the east.
Utica S h a l e - S c h e n e c t a d y F o r m a t i o n
L o r r a i n e G r o u p E n v i r o n m e n t s a n d Trilobites
D u r i n g later Middle O r d o v i c i a n , c a r b o n a t e deposition ceased
T h e Frankfort F o r m a t i o n , o f the Lorraine G r o u p , consists o f
and was abruptly followed by deposition of widespread, black
a series of dark gray to black shales with interbedded, thin, silty
Utica Shale facies (Figure 4 . 2 5 ) . T h e eastern p o r t i o n o f the
turbidites and o n e significant package (Hasenclever) of fine-
basin was b e g i n n i n g to receive increased a m o u n t s of coarse
grained, m u d d y sandstones. T h i s package appears to represent a
siliciclastic sediments, primarily siltstone and sandstone turbidite
m i n o r sea-level lowstand or a drop in the relative sea level that
beds,
caused progradation or westward migration of the coarser silici-
Schenectady
eroding
Taconic
Formation,
Mountains
which
during
occur
the
closer
same
time
to
the
interval
(Figure 4 . 2 5 B ) .
clastic silt and sand facies over m u c h of central New York. This b u n d l e , however, is overlain by a return to dark gray shales,
T h r o u g h o u t m u c h o f the M o h a w k Valley, alternating c a r b o n -
referred to as Moyer Creek M e m b e r in the Utica region, and Deer
ates and shales of the Dolgeville F o r m a t i o n ( p r o b a b l e equivalents
River dark shales to the northwest. T h e s e upper Frankfort shales
of the u p p e r m o s t Rust or Steuben limestones) are abruptly over-
are notable in the area in R o m e , New York, for yielding extraor-
lain by a black, rusty weathering l a m i n a t e d shale, Utica (Indian
dinarily preserved fossils. T h e s e are displayed in thin beds of silty
Castle), with a b u n d a n t thin (1 to 2 cm thick) clay layers that r e p -
shale referred to as Beecher's Trilobite Bed that is exposed along
resent m e t a b e n t o n i t e s .
S i x M i l e Creek n o r t h of R o m e . T h e s e beds have yielded spectac-
These black shales are referred to herein as the Indian Castle Formation of the Utica Shale G r o u p .
T h e trilobite
Triarthrus
ularly
pyritized
Triarthrus
eatoni
specimens
with
preserved
appendages, in significant n u m b e r s in o n e thin band. T h e s e trilo-
of
bites were buried very rapidly by a thin, silty turbidite, probably
O n t a r i o , is found in the upper Indian Castle Shale i m m e d i a t e l y
c o m i n g out of the then-developed deltaic regions to the east. Very
spinosus, above
normally the
seen
Steuben
in
the
Limestone
Collingwood near
Holland
Formation Patent,
Oneida
early infilling of the appendages by fine-grained pyrite preserved these fossils exceptionally well. T h e y have been the subject of
County. Throughout
the
Mohawk
Valley
region,
black
shales
of
n u m e r o u s a n a t o m i c a l and t a p h o n o m i c studies. T h e similarly
varying age ranging up to 3 0 0 m thick constitute a relatively
pyritized
m o n o t o n o u s facies c o m p o s e d largely of black laminated g r a p -
beecheri are present but relatively rare.
tolite-rich shales. O n l y certain beds of the Indian Castle c o n tain o t h e r fossils, such as highly flattened o r t h o c o n i c nautiloids and pear
the trilobite to
have
Triarthrus eatoni.
been
particularly
Again, these trilobites a p adapted
to
the
trilobites
Exceptionally
Cryptolithus
well-pyritized
bellulus
cephalopod
arthrus s p e c i m e n s are also k n o w n
and
Cornuproetus?
remains
and
from the Frankfort
Tri-
(Deer
River) shales in the vicinity of Constableville, Lewis County, and
low-energy,
W h e t s t o n e Gulf, Lewis C o u n t y , in northwestern New York State.
low-oxygen e n v i r o n m e n t s represented by the Utica Shale deposi-
T h e s e beds show increasingly thick, silty and sandy beds that rep-
tion. Waters were probably relatively deep and stagnant in the
resent distal or m o r e proximal turbidites or storm deposits; these
FIGURE 4 . 2 5 . New York maps during the late Middle Ordovician and the Upper Ordovician. A. Late Middle Ordovician. B. Late Ordovician. C. Cross section of the plate movement during Late Ordovician. From Isachson et al. (1991). Printed with permission of the New York State Museum, Albany, N.Y.
80
THE
PALEOZOIC
GEOLOGY
OF
NEW
YORK
beds are interbedded with m e d i u m to b r o w n i s h gray shales that
(Figure 4 . 2 8 ) . Locally, bundles o f f i n e - g r a i n e d sandstone, s o m e o f
may represent b a c k g r o u n d c o n d i t i o n s . T h e s t o r m beds typically
t h e m c o n t a i n i n g a n i m a l burrows, are also present within the
display a hash or lag of shelly material that includes b r a c h i o p o d s ,
Q u e e n s t o n , for e x a m p l e , at Rochester. However, the presence of
bivalves, and c r i n o i d stems on their bases. T h e s e coarser skeletal
small, limey nodules, referred to as calcretes, in certain horizons
debris layers grade upward into fine grainstones and siltstones
suggests the development of s o i l - f o r m i n g features within the
that c o m m o n l y display h u m m o c k y c r o s s - l a m i n a t i o n ; these low-
Q u e e n s t o n F o r m a t i o n . T h e presence o f calcretes implies long
m o u n d e d l a m i n a t i o n s , typically c o n v e x - u p w a r d , are thought to
periods of aerial exposure during the deposition of these muds.
be f o r m e d by the interference of s t o r m waves and currents in rel-
We visualize the Q u e e n s t o n as representing a broad alluvial flood-
atively shallow waters. Tops of s a n d s t o n e beds also display fea-
plain of possibly m e a n d e r i n g streams that originated in the
tures such as interference and w a v e - f o r m e d ripple marks that
Taconic Highlands and spread sheetlike masses of sediment over
further indicate a relatively shallow-water origin for these beds.
a wide tract of the Appalachian Basin. Red coloration, together
T h e Pulaski beds are d o m i n a t e d by b r a c h i o p o d s , c l a m s , and a few
with the calcretes, indicates subaerial exposure for m u c h of the
species of crinoids. However, trilobites are k n o w n at certain levels
unit in New York State, at least. However, to the west, the Q u e e n -
and
ston interfingers with the gray calcareous m u d s t o n e and even
include
Cryptolithus
bellulus,
as
well
as
some
Flexicalymene
species and Isotelus species, which m a y o c c u r in thin, skeletal hash
brachiopod-
beds. T h e s e beds represent s o m e o f the highest o c c u r r e n c e s o f
H a m i l t o n , O n t a r i o . Still farther west, the Q u e e n s t o n appears to
and
bryozoan-rich
limestones
northwest
of
these trilobites. In New York the overlying beds of the Oswego
b e equivalent t o the R i c h m o n d G r o u p o f the C i n c i n n a t i , O h i o ,
and Q u e e n s t o n f o r m a t i o n s represent n e a r s h o r e o r n o n m a r i n e
area, part of the section n o t e d for exceptionally well-preserved
fades inappropriate for the preservation of trilobites, although
fossils, including a b u n d a n t trilobites of the genera Flexicalymene,
these genera persisted, with a b u n d a n t Flexicalymene and Isotelus
Isotelus, and others. H e n c e , these organisms lived on in the later
remains c o m m o n in the R i c h m o n d G r o u p in southwestern O h i o .
part of the O r d o v i c i a n in the m i d c o n t i n e n t , while New York State
Cryptolithus and
developed into a delta plain and tidal fiat c o m p l e x .
Isotelus and the entire trinucleid
and
asaphid
trilobite groups to which they b e l o n g appear to have b e c o m e extinct in the Late O r d o v i c i a n crisis, which affected m o r e than 2 0 % o f m a r i n e families.
T h e latest
p o r t i o n o f the Ordovician
Period
(Gamachian
Stage) is not recorded in New York, or in most of the m i d c o n t i nent of North A m e r i c a . T h e Q u e e n s t o n is terminated by a m a j o r
T h e reported trilobites of the U p p e r O r d o v i c i a n are as follows:
erosional
u n c o n f o r m i t y (referred
to as
the Cherokee
Unconfor-
mity; Figures 4 . 1 and 4 . 2 6 ) . T h i s erosion surface increases in magCalyincnc?
conradi
Ceraurinus
marginatus
Calyptaulax Ceraurus
cf.
beecheri
Cryptolithus
Flexicalymene
granulosa
Flexicalymene
stegops
Odontopleura Proetus
ceralepta
spurlocki
Triarthrus
eatoni
Triarthrus
spinosus
Isotelus
nitude to the east along the Q u e e n s t o n clastic wedge. Ultimately, it cuts down through the entire thickness of the Q u e e n s t o n (over 4 0 0 m) and through the underlying Pulaski, Frankfort, and upper
bellulus
parts of the Utica or Schenectady f o r m a t i o n s (Figures 4 . 1 2 and
meeki
pulaskiensis
4 . 2 6 ) . T h i s suggests that several things were happening in the Late
hudsonica
O r d o v i c i a n . First, there was a period of uplift in the eastern
Otarion? Pseudogygites Triarthrus
callicephalus
sp.
Cornuproetus? Homotelus
C.
p o r t i o n s of the old Q u e e n s t o n delta. T h i s might reflect renewed
latimarginatus
o r o g e n i c or m o u n t a i n - b u i l d i n g activity at the very end of the
glaber
O r d o v i c i a n or Early Silurian, or possibly isostatic forces (buoya n c y forces) that caused the eastern areas, formerly part of the m o u n t a i n belt, to b o b upward in m u c h the same way that land
Upper O r d o v i c i a n O s w e g o a n d Q u e e n s t o n F o r m a t i o n s T h e record of benthic life in the highest part of the O r d o v i c i a n
r e b o u n d s after removal of the weight of a glacier (Figure 4 . 2 5 B ) .
deposits in New York is sparse. T h e Pulaski gives way upward to
T h i s " p o p - u p " p h e n o m e n o n or isostatic r e b o u n d would be the
coarser g r a y - a n d - m a r o o n - m o t t l e d sandstones o f the Oswego For-
result of erosional redistribution of sediments from the old thrust
m a t i o n . Here, a b u n d a n t wave m a r k s , desiccation cracks, and other
belt of the Taconic M o u n t a i n s and out into a wider tract of the
features toward the top indicate shallowing of the O r d o v i c i a n
interior of North A m e r i c a . A second event that may have c o n -
seafloor effectively to sea level. T h i s shallowing was p r o d u c e d by
tributed to the development of a m a j o r widespread u n c o n f o r m i t y
the rapid in-filling of clastic s e d i m e n t s that were being shed out of
or erosion surface at the end of the Ordovician was the develop-
the n o w eroding Taconic Highlands to the east. T h e effect of this
m e n t of extensive continental glaciers in the region that today
was the o u t w a r d - b u i l d i n g or progradation of the so-called Q u e e n -
is
ston delta c o m p l e x into the Appalachian foreland basin.
have locked up a considerable a m o u n t of water as glacial ice and
Saharan Africa.
These
Late Ordovician
ice sheets would
along
thereby caused a d r o p in sea level from the Late Ordovician on
the s o u t h shore o f Lake O n t a r i o f r o m O s w e g o C o u n t y westward
the o r d e r of perhaps 100 m. T h i s is reflected in successions of rock
t o the Niagara G o r g e , consists o f m a r o o n - r e d blocky m u d s t o n e
worldwide as a m a j o r erosion surface associated with regression
with occasional streaks of greenish gray siltstone and sandstone
of seas. T h i s t i m e also corresponds to o n e of the great mass
T h e overlying Q u e e n s t o n
F o r m a t i o n , well
exposed
SILURIAN
81
PERIOD
FIGURE 4 . 2 6 . Ordovician/Silurian unconformities. A. Ordovician/Silurian unconformity. Upper Ordovician, black Frankfort S h a l e (a) is sharply overlain by Lower Silurian, light gray O n e i d a c o n g l o m e r a t e and s a n d s t o n e (b), which g r a d e s upward into gray Sauquoit S h a l e . Cut along Rte. 1 7 1 , Frankfort G o r g e of Moyer Creek, Frankfort, Herkimer County. B. Angular C h e r o k e e unconformity (arrow) b e t w e e n Ordovician Austin Glen Formation ( b ) (nearly vertical b e d s on right side) and gently dipping u p p e r m o s t Silurian Rondout Formation (a). Note that the unconformity, p r o d u c e d by erosion of the folded Taconic terrane, w a s later rotated to 45 d e g r e e s during the Devonian A c a d i a n Orogeny. Exit from Rte. 23 to 2 3 B , Catskill, G r e e n e County.
extinctions in Earth's history and o n e that decimated m a n y trilo-
recovery from m a j o r Late O r d o v i c i a n extinction and ended with
bites, such as the genux Isotelus.
m i n o r extinction before the D e v o n i a n . T h e r e is really not a m a j o r S i l u r i a n - D e v o n i a n break in m o s t areas. T h e Silurian marks a
Silurian Period
return to g r e e n h o u s e c o n d i t i o n s following the Late Ordovician glaciation, but there appears to have been s o m e lingering glacia-
T h e Silurian Period was a relatively short span ( 4 3 8 to 4 0 8
tion in the paleo-Andes M o u n t a i n s of S o u t h A m e r i c a through the
million years ago) (Figures 4.1 and 4 . 2 7 ) that c o m m e n c e d with
Early Silurian. Middle and Late Silurian climates appear to have
THE
82
PALEOZOIC
GEOLOGY
OF
NEW
YORK
FIGURE 4.27. Stratigraphic chart of the Silurian rocks in New York. The n u m b e r s are millions of years before present. M o d i f i e d from Brett et al. (1985).
been quite equable worldwide, with lots of shallow c a r b o n a t e
(Figures 4.5 and 4 . 2 6 ) . E t t e n s o h n and Brett ( 1 9 9 8 ) recognized
deposition and s o m e return to stagnation and black shale devel-
a third and final tectophase of Taconic O r o g e n y in the Early
o p m e n t in deeper basins.
Silurian; this m o u n t a i n - b u i l d i n g activity produced a new clastic
T h e eastern side of Laurentia, n o w a b o u t 25 to 30° south latitude, experienced the f i n a l r u m b l e s o f the Taconic O r o g e n y
wedge, the T u s c a r o r a - M e d i n a f o r m a t i o n s , and pulse of westward subsidence.
SILURIAN
83
PERIOD
Baltica (Ancestral Europe) had m o v e d northward through the
( M i d d l e t o n et al. 1 9 8 7 ) . T h e s e s e d i m e n t s appear to represent
Ordovician and now collided with n o r t h e r n Laurentia to f o r m
a reworking of older O r d o v i c i a n siliciclastics, as the Whirlpool
the widespread Caledonian
created
locally contains very m i n o r thin seams of greenish gray shale that
Euramerica ( o r " O l d Red C o n t i n e n t " ) straddling the p a l e o e q u a -
not o n l y c o n t a i n early Silurian a c r i t a r c h s , small microfossils
tor (Figure 4 . 5 ) . At the same t i m e the m i c r o c o n t i n e n t of Avalo-
representing p r o b a b l e algal resting cysts, but also acritarchs
nia was converging on (present-day) eastern N o r t h A m e r i c a ,
reworked f r o m the O r d o v i c i a n .
making initial
New
Trilobites evidently were present in s o m e of these environm e n t s , but their b o d y fossils are rare. T h e upper p o r t i o n of the
appears to have been s o m e orogenesis during the M i d d l e Silurian
W h i r l p o o l S a n d s t o n e is distinctly m a r i n e and locally shows h u m -
in
m o c k y c r o s s - l a m i n a t e d s a n d s t o n e beds with m i n o r fossil debris.
North
in
the
America
northern
Europe and
England region in the Late Silurian or Fail}' Devonian. T h e r e eastern
contact
O r o g e n y in
(Laurentia),
M a r i t i m e and
termed
the
Salinic
Orogeny, as evidenced by a renewed pulse of subsidence and west-
R e m n a n t s of starfish and c r i n o i d s have been f o u n d in the upper
ward migration of the foreland basin.
layer of the W h i r l p o o l in O n t a r i o , and farther west the Whirlpool
Sea level rose in the Early Silurian, following the lowest sea
grades laterally into or is overlain by the M a n i t o u l i n D o l o s t o n e ,
level at the end of a regression that p r o d u c e d the C h e r o k e e
a rather massive
Unconformity
locally c o n t a i n s a b u n d a n t b r a c h i o p o d s and m i n o r disarticulated
in
the
latest
Ordovician.
The
Silurian-Early
Devonian bundle of strata forms the Tutelo ( s e c o n d )
Phase
fine-grained
d o l o m i t i c c a r b o n a t e . T h i s unit
trilobite material. T h e probably equivalent massive Tuscarora
of Sloss's T i p p e c a n o e S u p e r s e q u e n c e . Sea level was quite high
Sandstone of Pennsylvania is generally devoid of body fossils but
throughout the mid Silurian but was beginning to fall in the later
contains
Silurian. Smaller-scale (third and fourth order) sequences were
resting traces o f trilobites.
developed owing to s h o r t e r - d u r a t i o n rises and falls of sea level during the Silurian in eastern N o r t h A m e r i c a .
abundant
traces
including
Rusophycus,
the
probable
In Niagara C o u n t y and westward into O n t a r i o the W h i r l p o o l S a n d s t o n e is overlain by dark gray to m e d i u m greenish gray
Although the Silurian is a relatively shorter interval of time
shales and with s o m e thin q u a r t z - r i c h sandstones. In western
than the Ordovician or the D e v o n i a n , Silurian rocks in New York
New York this Power Glen Shale tends to be sparsely fossiliferous.
State are highly varied, indicating a b r o a d range of depositional
O n l y m i n o r trace fossils, including Rmophycus, are f o u n d on the
environments. T h e Silurian can be subdivided into five m a j o r
base of sandstones at L o c k p o r t . At Niagara the unit is s o m e w h a t
divisions that are generally construed as groups (Figure 4 . 2 7 ) . In
m o r e fossiliferous, yielding a small fauna including snails, small
ascending order these are the (1) M e d i n a G r o u p : predominately
twiglike b r y o z o a n s , nautiloid c e p h a l o p o d s , and a single species
shales and sandstones of early Silurian age; ( 2 ) C l i n t o n G r o u p : a
of small c r i n o i d . Westward in O n t a r i o the unit b e c o m e s even
heterogeneous group c o m p o s e d o f shales, m i n o r sandstones, and
m o r e fossiliferous, and
shell-rich carbonates with m i n o r h e m a t i t e beds; ( 3 ) L o c k p o r t
a b u n d a n t remains o f several species o f b r y o z o a n s , b r a c h i o p o d s ,
G r o u p : predominantly d o l o m i t i c c a r b o n a t e s in western New
c r i n o i d s , and starfish. Trilobites tend to be u n c o m m o n in these
York, grading eastward into dark gray or greenish shales and thin
beds, but a few r e m a i n s of c a l y m e n i d s and dalmanitids have been
stromatolitic limestones; (4) Salina G r o u p : Upper Silurian shales,
collected.
near H a m i l t o n , O n t a r i o , it contains
carbonates, and evaporites; and ( 5 ) Bertie and R o n d o u t G r o u p s :
T h e Power Glen Shale and laterally equivalent C a b o t Head
dolomitic limestones and dolostones with s o m e shales and m i n o r
Shales appear to have a c c u m u l a t e d in shallow offshore shelf or
evaporites.
pro-deltaic settings of early M e d i n a . D a r k gray and greenish colo r a t i o n , as well as an a b u n d a n c e of pyrite at s o m e levels, suggests a c c u m u l a t i o n under low-oxygen, quiet water c o n d i t i o n s . Perhaps
Early Silurian
the i n n e r - s h e l f m u d s were deposited in a sheltered, muddy
Medina G r o u p
lagoon. However, s o m e w h a t m o r e o f f s h o r e sediments in the
T h e Early Silurian Medina S a n d s t o n e of New York and its equivalents, the Tuscarora sandstones and c o n g l o m e r a t e s of the
vicinity o f H a m i l t o n , O n t a r i o , d o show a b u n d a n t storm deposits, indicating deposition by s t o r m waves and currents.
central Appalachian region, represent a renewed influx of silici-
T h e higher beds of the M e d i n a G r o u p in western New York,
clastic sediments following the m a j o r e n d - O r d o v i c i a n u n c o n f o r -
assigned to the G r i m s b y F o r m a t i o n , are primarily reddish and
mity or period of erosion. T h e M e d i n a G r o u p is c o n f i n e d to
white-mottled, quartz-rich,
western and west-central New York, pinching out eastward in the
stones interbedded with green and red m u d s t o n e s . Generally,
vicinity o f O n e i d a , O n e i d a C o u n t y (Figure 4 . 2 8 ) . T h e M e d i n a i s
these sediments are sparsely fossiliferous, particularly east of
fine-grained
sandstones and silt-
characterized by quartz-rich sandstones and shales, m a n y of
L o c k p o r t , New York. But in the west they may contain abundant
which are red.
shells of lingulid b r a c h i o p o d s , a
In western New York and O n t a r i o the basal unit is a quartzose
few species of clams, and
even b r y o z o a n s at Niagara G o r g e . T h e presence of abundant
sandstone with trough c r o s s - b e d d i n g , the W h i r l p o o l S a n d s t o n e ,
b u r r o w i n g with m a n y p r i m a r y sedimentary structures, such as
which
wave and current ripple m a r k s , m i n o r trough and h u m m o c k y
may
represent,
in
part,
nonmarine
stream
deposits
84
THE
PALEOZOIC
GEOLOGY
OF
NEW
YORK
FIGURE 4.28. A. Ordovician-Silurian (Cherokee) unconformity (arrow). U p p e r O r d o v i c i a n , dark m a r o o n Q u e e n s t o n Shale (a) is sharply overlain by light gray Whirlpool S a n d s t o n e (Lower Silurian) (b). In turn, the Whirlpool g r a d e s a b r u p t l y u p w a r d into gray Power Glen Shale ( M e d i n a Group) (c). Cut on West J a c k s o n Street, Lockport, Niagara County. B. O r d o v i c i a n Lower Silurian s u c c e s s i o n . U n c o n f o r m i t y (arrow) at the t o p of the U p p e r O r d o v i c i a n Queenston Shale (a) is overlain by Lower Silurian Medina G r o u p (b). The white b a n d at the top of the M e d i n a is the K o d a k Sandstone (c). This unit is overlain, in turn, by green M a p l e w o o d Shale (d) of the Clinton G r o u p . G e n e s e e River G o r g e . Rochester, Monroe County.
cross-stratification, rare desiccation c r a c k s , evidence o f c h a n n e l -
upward to h u m m o c k y cross-laminated sandstone beds that may
ing and soft sediment d e f o r m a t i o n in the f o r m of load casts
be capped by thin lag beds of bryozoans and / inguhi brachiopod
and b a l l - a n d - p i l l o w - s t r u c t u r e s all point to deposition in very
shell hash representing m i n o r deepening events. In Rochester,
shallow waters associated with outer- to inner-tidal flats. W i t h i n
New York, s o m e w h a t different, fining upward cycles seem to have
the M e d i n a , o n e m a y recognize small-scale, c o a r s e n i n g , upward
s h a r p - b a s e d , channel-fill sandstones at the b o t t o m s , which are
cycles in western New York that range from m a r o o n m u d s t o n e s
often extensively burrowed by large wormlike organisms that pro-
SILURIAN duced
8b
PERIOD Daedalus, apparently as
ironstones are c o m m o n l y associated with phosphatic nodules and
feeding burrows in muddy sands. T h e upper reddish m u d s t o n e s
structures called Arthrophycus or
flooding surfaces (surfaces with very low sedimentation rates
in higher parts of the cycles apparently reflect upper tidal-flat
during deepening episodes).
conditions, where low-energy c o n d i t i o n s prevailed, allowing fine-
T h e lowest part of the C l i n t o n G r o u p c o m p r i s e s greenish gray
grained muds to drop out of suspension. All of these sediments
shales, the Neahga or M a p l e w o o d of western New York, overlain
apparently accumulated from c o n t i n u e d erosion and deposition
In- thin limestones. T h e Neahga is a highly fissile, very soft, chippy
o f f m o u n t a i n o u s highlands to the s o u t h - s o u t h e a s t . At present, it
shale that like the Power Glen seems to represent nearshore but
appears that a late phase of the Taconic O r o g e n y o c c u r r i n g within
dysaerobic m u d d y b o t t o m c o n d i t i o n s . T h e M a p l e w o o d contains
the early part of the Silurian m a y have uplifted or re-uplifted
very a b u n d a n t microfossils of acritarchs, algal resting cysts, and
these source terrains.
s o m e early plant spores but is almost devoid of macrofossils. A
Trilobites are extremely rare b o d y fossils in the upper sand-
very meager fauna, including o n e species o f calymenid, o n e
stones of the Medina G r o u p . Two persistent, often light gray or
odontopleurid
pinkish sandstones, the T h o r o l d and the Kodak, contain a b u n -
o b t a i n e d f r o m a basal p h o s p h a t e - r i c h layer that immediately
dant trace fossils but very few body fossils. Near Rochester the
overlies the u n c o n f o r m i t y at the b o t t o m of the M a p l e w o o d .
Kodak bears remains of beautifully preserved traces of trilobite
However, in general, the c o n d i t i o n s appear to have been unfa-
trilobite,
and
a
few
brachiopods,
has
been
activity, although as yet no b o d y fossils have been f o u n d . T h e s e
vorable for benthic or b o t t o m - d w e l l i n g life during deposition of
include the coffee b e a n - s h a p e d Rusophycus as well as delicately
the M a p l e w o o d m u d s .
detailed scratch marks produced by trilobites walking on the tips
T h e M a p l e w o o d grades eastward into a sandy, hematite-rich
of their claws. T h e fact that slabs of sandstone from Glen Edith
c o n g l o m e r a t e that is generally lacking in fossils. However, it
near Irondequoit Bay, M o n r o e County, display trilobite trackways
grades upward and laterally to the west into t h i n - b e d d e d lime-
superimposed on m u d cracks suggests that these trilobites m a y
stones and fossil-rich h e m a t i t e beds. T h e s e limestones, the Rey-
have lived in a very shallow water area that was subject to peri-
nales F o r m a t i o n , are rich in b r a c h i o p o d s , particularly the large
odic exposure and desiccation.
robust Pentamerus, which appears to have f o r m e d shell banks
Toward the end of Medina deposition, uplift of a b r o a d arch-
in shallow shoal areas on the seafloor. To the west, these b r a -
like feature, the Algonquin axis or Findley Arch, to the west of
c h i o p o d - r i c h shoals and crinoidal grainstones pass laterally into
New York State elevated parts of the M e d i n a seafloor above sea
m o r e nodular, shaly, and probably m o r e offshore limestones.
level and caused erosion to bevel down through the highest beds
T h e s e facies c o n t a i n smaller b r a c h i o p o d s , a b u n d a n t and diverse
of the Medina, producing a widespread u n c o n f o r m i t y that sepa-
b r y o z o a n s , c r i n o i d s , and a few trilobites. Particularly notable in
rates this unit from the overlying Clinton G r o u p (Figure 4 . 2 8 B ) .
these beds are a b u n d a n t cephala and pygidia of the trilobite
T h e T u s c a r o r a - S h a w a n g u n k - M e d i n a clastic wedge consists of quartz-rich sandstones overlying the angular T a c o n i c U n c o n f o r mity in the Appalachians, which seem to record renewed uplift
Encrinurus. Reported f r o m
the Reynales are the following species of
trilobites:
and sedimentation. In the Niagara region, these show a transgressive succession from n o n m a r i n e and nearshore sandstones, to
Bumastus sp.
deeper marine gray shales, followed by a shallowing (regression)
Encrinurus cf. E.
into tidal flat and n o n m a r i n e red beds.
Scutellum
Calymene rayhesli
sp.
Eophacops trisulcatus
niagarensis
Green and purplish shales of the overlying S o d u s F o r m a t i o n
Middle Silurian
in west-central New York represent a return to shallow water Lower C l i n t o n G r o u p
m u d d y c o n d i t i o n s similar to but s o m e w h a t different from those
Middle Silurian (late Llandovery series) m i x e d shales, c a r -
of the M a p l e w o o d . T h e s e m u d d y seafloors supported a modest
bonates, and ironstones of the lower C l i n t o n G r o u p record the
diversity of b r a c h i o p o d s d o m i n a t e d by the small atrypid Eocoelia,
wearing down of Taconic m o u n t a i n o u s source terranes to the east
small bryozoans, a few c r i n o i d ossicles, the conical fossil Tenta-
and a shift back to o p e n m a r i n e sediments. O n e distinctive
culites, and scattered s p e c i m e n s of small tabulate corals. A few
feature is the widespread " C l i n t o n iron o r e s " ; these f a m o u s fossil-
trilobites make up the r e m a i n d e r of the fauna. Both Diacalymene
rich and oolitic hematites have been m i n e d extensively f r o m
rostrata and Eophacops trisulcatus have been extracted from these
near B i r m i n g h a m , Alabama, to central New York for m a k i n g steel
beds. Here c o n d i t i o n s alternated between dysoxic and s o m e -
and red paint oxides. T h e s e beds probably were associated
what better oxygenated, as indicated by the green and purple
with enrichment of iron in sediments due to deep weathering of
b a n d i n g typical
laconic uplifts. Hematite coatings on grains precipitated under
temporarily hospitable to b e n t h i c assemblages of a very shallow-
conditions
in
water restricted type. T h e s e m u d s apparently represent accu-
muddy sediments, during times of sediment starvation. Hence,
m u l a t i o n s in a b r o a d shallow-water lagoonal setting inboard of
of
fluctuating
oxidizing-reducing
conditions
of the
unit, and
the seafloor was at least
THE
86
PALEOZOIC
GEOLOGY
OF
NEW
YORK
offshore, b r a c h i o p o d - r i c h shoals, which at that t i m e were as far
underlying middle and to the west of the lower Clinton units. It
west as O h i o .
is again a particularly oolitic-rich ironstone that contains a b u n -
T h e Wolcott F o r m a t i o n represents a return to Reynales-like
dant, small (1 to 2 m m ) spheroidal bodies of hematite that appear
c o n d i t i o n s in which a b u n d a n t p e n t a m e r i d b r a c h i o p o d s o n c e
to have f o r m e d by accretion of i r o n - r i c h coatings on grains that
again flourished and f o r m e d shell banks in west-central New
were at least intermittently rolled on the sea b o t t o m . This unit
York. However, an u n c o n f o r m i t y has removed western p o r t i o n s
probably represents a deposit accumulated during sea-level deep-
of the Wolcott so it is not possible to trace these facies westward
ening in which the fine-grained portion was winnowed away,
past Wayne C o u n t y into offshore n o d u l a r sediments c o m p a r a b l e
associated with an episode of a very widespread rise in sea level that o c c u r r e d globally during mid Silurian times. It is well dated
to those seen in the western Reynales. T h i n hematite bands, usually only a few c e n t i m e t e r s thick but traceable over distances of tens of kilometers, are f o u n d at several
by ostracods and sawblade-like graptolites that o c c u r in the interbedded shales.
levels within the lower part of the C l i n t o n G r o u p . As n o t e d , these
Beds of black-green shale of the mid Silurian Williamson
appear to represent periods of m a r i n e s e d i m e n t starvation in a
F o r m a t i o n and its eastern equivalent Willowvale Shale carry an
shoal margin e n v i r o n m e n t in which ferrous iron b e c a m e c o n -
a b u n d a n t fossil assemblage. Fossils typically are poorly preserved
centrated in pore-waters and precipitated out as coatings and
in the shales but they may include over a hundred species of
ooidlike grains on the seafloor. Reworking of these grains into
b r a c h i o p o d s , b r y o z o a n s , the small " b u t t o n " coral Palacocyclus,
windrows or piles c o n c e n t r a t e d
the iron oxide c o m p o n e n t s ,
crinoids, and
trilobites.
Both
Dalmanites and
Calymene species
making them lean iron ores. T h e s e ores are mostly "fossil ores,"
are relatively a b u n d a n t in the Willowvale of central New York.
meaning that they contain a b u n d a n t f r a g m e n t a r y fossils, espe-
To the west, the m e d i u m gray shales give way laterally to green
cially c r i n o i d ossicles, bits of b r y o z o a n s , and shell fragments.
satiny-smooth
Again trilobites, especially c a l y m e n i d s , are present but only as
s o m e t i m e s sandy shales that yield a great a b u n d a n c e locally of the
highly c o m m i n u t e d debris.
sawblade
T h e middle part of the C l i n t o n is represented by the Sauquoit Shales
and
their
eastern
reddish
sandstone
equivalent
the
clay
shales,
monograptid
alternating graptolite
with
black-laminated,
Monograptus
clintonensis,
which enables correlation of the Willowvale and Williamson Shales with o t h e r deposits globally that
represent this mid
Otsquago F o r m a t i o n in the Utica area and eastward. T h e s e units
Silurian highstand or sea-level rise event. T h e Williamson Shales
may be in excess of 30 m thick, and e x p a n d dramatically to the
in
southwest into a succession, up to 140 m thick, of purplish green
f o s s i l s , although s o m e beds carry small b r a c h i o p o d s and rare
the
Rochester
area
generally contain
few o t h e r
benthic
shales referred to as Rose Hill in Pennsylvania and M a r y l a n d . T h e
s p e c i m e n s of the trilobite Calymene have been f o u n d . Overall the
Sauquoit Shale from the middle part of the C l i n t o n G r o u p rep-
W i l l i a m s o n - W i l l o w v a l e Shales probably record the deepest-water
resents c o n d i t i o n s quite similar to those of the Sodus and M a p l e -
interval during deposition of the Silurian in New York State.
wood m u d s , and like t h e m it tends to c a r r y a restricted fauna,
B o t t o m c o n d i t i o n s range from anoxic or having very low oxygen,
although the trilobite Calymene is relatively c o m m o n and the
near the basin center, to fully oxygenated conditions favorable to
genus Dalmanites has also been reported f r o m these shales.
life in central New York Willowvale sections.
Upper C l i n t o n G r o u p
Sandstone represent s o m e w h a t shallower water c o n d i t i o n s in
T h e overlying
Rockway D o l o s t o n e and equivalent
Dawes
A very widespread u n c o n f o r m i t y separates the middle C l i n t o n
which r h y t h m i c limestones or calcareous sandstones a c c u m u -
and lower C l i n t o n shales from the overlying upper part of the
lated, alternating with shales. Again, fossils tend to be sparse
Clinton G r o u p . D u r i n g this medial part of Silurian t i m e , m o r e
because of p o o r preservation in these beds. But a few species of
dramatic arching of the sea b o t t o m in the vicinity of the Algo-
brachiopods,
nquin Arch (near H a m i l t o n , O n t a r i o ) and farther east exposed
graptolites, mostly dendroids (or brushy graptolites), and rare
m a j o r parts of the older C l i n t o n sediments to erosion and pro-
trilobites, such as Dalmanites, have been f o u n d in these beds.
duced a widespread beveling-surface u n c o n f o r m i t y that eroded
In
western
including
the
New York
the
large
form
Rockway
Costistricklandia,
consists
of pale
and
to
o f f the western edges of the middle and lower C l i n t o n units.
m e d i u m gray, argillaceous dolostones with interbedded greenish
H e n c e , a good deal of Middle Silurian t i m e may be missing at this
gray shales. Overall, the Rockway appears to represent an off-
important unconformity.
shore m u d d y c a r b o n a t e unit deposited well below wave-base
T h e upper part of the C l i n t o n G r o u p is a varied succession of
and under s o m e w h a t restricted c o n d i t i o n s . It grades eastward
shales a n d c a r b o n a t e s that are readily g r o u p e d into two u n c o n -
and southeastward into the Dawes S a n d s t o n e of central New
f o r m i t y - b o u n d sequences o r packages. T h e lower consists o f
York, an interbedded, h u m m o c k y c r o s s - l a m i n a t e d , fine-grained
the W e s t m o r e l a n d
sandstone and shale unit with the beautiful trilobite trace fossil,
Hematite
(locally), W i l l i a m s o n - W i l l o w v a l e
shales, and the R o c k w a y F o r m a t i o n and its lateral eastern equivalent, the Dawes S a n d s t o n e . T h e basal hematite b e d , or Westm o r e l a n d , rests u n c o n f o r m a b l y on
the beveled edges of the
Rusophycus. T h e Rockway and its equivalents are sharply overlain by a thin, widespread blanket deposit of crinoidal limestone. T h i s unit,
FIGURE 4.29. M a p s of New York. A. Early W e n l o c k times d u r i n g the d e p o s i t i o n of the Irondequoit Limestone. B. Mid Wenlock d u r i n g the deposition of the Rochester Shale. C. Cross section s h o w i n g the a p p r o a c h of Avalon with proto North A m e r i c a . C is from Isachson et al. (1991). Printed with p e r m i s s i o n of the N e w York State M u s e u m , Albany, N.Y
THE
88
FIGURE 4.30.
PALEOZOIC
GEOLOGY
OF
NEW
YORK
Irondequoit-Rochester b i o h e r m at the
upper part of the M i d d l e Silurian Clinton G r o u p . The sharp contact at the knee level of William G o o d m a n is the u n c o n f o r m a b l e c o n t a c t of R o c k w a y Dolostone (a) a n d massive Irondequoit Limestone (b). The lens-shaped b o d y at the top of the Irondequoit is a small b i o h e r m ("reefs") (arrow) of b r y o z o a n s a n d algae. It o c c u r s at the c o n t a c t of the dark gray Rochester Shale (c). N i a g a r a G o r g e , Lewiston, Niagara County.
4.29),
resent very small buildups or "reeflets" that developed on the
consists almost entirely o f the disarticulated and c o m m o n l y
seafloor during a t i m e of deepening. T h e s e m o u n d s , however,
abraded skeletal remains of crinoids and cystoids. However, there
have yielded s o m e intriguing fossil deposits that are not found
are s o m e thin, interbedded shaly units, and in the R o c h e s t e r area,
elsewhere within the Irondequoit L i m e s t o n e or the overlying
referred
to
as
the
Irondequoit
Limestone
(Figure
the Irondequoit is s o m e w h a t finer-grained and carries a lower
R o c h e s t e r Shale. For e x a m p l e , pockets of greenish shale within
diversity of fauna typified by a few species of b r a c h i o p o d s , of
the c r e a m - c o l o r e d , f i n e - g r a i n e d limestone o f the m o u n d s i n
which Whitfieldella is a c o m m o n e l e m e n t . Also in this area, as
Niagara C o u n t y yield extremely a b u n d a n t remains of the trilo-
well as in Niagara County, small (up to 5m across and 2m h i g h ) ,
bite genera Bumastus and Illaenoides. T h e s e relatively large fossils,
irregular, lenticular m o u n d s , or b i o h e r m s , o c c u r within the I r o n -
up to 3 cm across, appear to represent the remains of reef- or
dequoit (Figure 4 . 3 0 ) . In Niagara C o u n t y these o c c u r mainly at
b i o h e r m - d w e l l i n g trilobites that accumulated or collected in the
the upper c o n t a c t of the crinoidal limestone and extend upward,
small pockets and cavities within the b i o h e r m framework. Also
s o m e t i m e s as m u c h as 1 to 2 m (4 to 5 feet), into the overlying
found
R o c h e s t e r Shale. T h e s e are rather a m o r p h o u s masses of very-
rochesterense, and a new species of Diacalymene that is also rather
fine-grained ( m i c r i t i c ) l i m e s t o n e with s o m e leaflike b r y o z o a n s
large and represented by nearly c o m p l e t e articulated remains
that apparently helped s u p p o r t the m o u n d s . T h e b i o h e r m s rep-
from the Niagara G o r g e .
in
these
associations
are
a
Cheirurus
sp.,
Scutellum
SILURIAN
89
PERIOD
T h e Irondequoit and its b i o h e r m s represent a shallow, highly
of the Rochester, like the middle p o r t i o n of the Lewiston Member,
agitated shelf e n v i r o n m e n t . Water depths were close to n o r m a l
is characterized by dark gray, nearly barren shales in m u c h of
wave-base, ranging from perhaps 10 to 20 m in western New York
western New York. Nonetheless, s o m e bedding planes contain
and no m o r e than 20 to 30 m in the slightly deeper waters a r o u n d
a b u n d a n t remains, mostly disarticulated, as well as articulated
Rochester. T h e skeletal remains of crinoids and cystoids were
s p e c i m e n s of the trilobite genera Dalmanites and Trimerus. These
reworked and accumulated to thicknesses of up 3 or 4 m. C o n -
dark, sparsely fossiliferous shale facies, representing deeper por-
sidering that it takes about 1 5 , 0 0 0 average-sized crinoids to make
tions of the R o c h e s t e r sea, were deposited during relative rises in
1 m o f limestone, the total n u m b e r o f e c h i n o d e r m s represented
the sea level. H e r e , high rates of s e d i m e n t a t i o n c o m b i n e d with
in these beds is stunningly high ( 1 0 ' ° or even 1 0
low-oxygen c o n d i t i o n s near the substrate m a d e the b o t t o m c o n -
3
12
individuals).
These organisms flourished in shallow, relatively clean waters
ditions inhospitable for m o s t invertebrate species. Nonetheless,
associated with a m a j o r lowering of relative sea level in New York
s o m e trilobites, as scavengers, appear to have thrived in these
State. To the southeast, the Irondequoit skeletal limestone grades
e n v i r o n m e n t s . Shallower p o r t i o n s of the Rochester are repre-
first into hematitic limestone (the Kirkland F o r m a t i o n ) a n d
sented by banks of b r y o z o a n s and e c h i n o d e r m s (crinoids and the
beyond into quartzose, cross-bedded sandstones of the upper
cystoid Caryocrinites). Trilobites were less d o m i n a n t here but are
Herkimer F o r m a t i o n . A few trilobites are reported from the
represented by a greater diversity of species.
Irondequoit, including the following:
H e r k i m e r S a n d s t o n e , the eastern equivalent of the Rochester Shale, represents sandy shallow shelf to n e a r s h o r e e n v i r o n m e n t s .
Bumastus sp.
Diacalymene
Calymene sp.
Cheirurus
Liocalymene clintoni
Scutellum
sp.
It
sp.
yields
Trimerus
and
Dalmanites
specimens
and
excellently
preserved trilobite trace fossils, especially the large resting trace
rochesterense
Rusophycus. T h e paleogeographic distribution
of the trilobites
in
the
Irondequoit and its lateral equivalents, the Kirkland and Keefer
Lewiston M e m b e r is of interest. T h e trilobites east of Rochester
formations, are overlain sharply, but apparently c o n f o r m a b l y , by
are different f r o m those west of this area. Differences are at the
gray m u d s t o n e s of the Rochester F o r m a t i o n . Perhaps no Silurian
species as well as genus level. C e r t a i n genera such as Arctinurus,
unit in North America is m o r e noted for its exquisite fossils than
Decoroproetus,
the Rochester. Although m u c h of the unit is relatively sparsely
have been f o u n d o n l y in the west, while Cheirurus, Maurotarion,
fossiliferous, a total fauna of over 2 0 0 species of invertebrate
and
fossils is k n o w n from the Rochester Shale, including over 20
Dalmanites and Calymene o c c u r b o t h east and west of Rochester,
species o f trilobites. T h i n lenses o f b r a c h i o p o d - and b r y o z o a n -
but
rich m u d s t o n e s and argillaceous limestone yield prolific faunas,
Trimerus are
with over 80 species of bryozoans alone k n o w n from the middle
delphinocephalus is also f o u n d in equivalent age beds in England.
beds of the Rochester. In western New York the unit is divisible into two m e m b e r s : a fossil-rich lower half, b o u n d e d on its top by
Deiphon,
Dicranopeltis,
Staurocephalus have b e e n they
are
represented
found
in
found
Illaenoides, to
the east.
by different
both
the east
and
species.
Radnoria
T h e genera Bumastus and
and the west.
Trimerus
Rochester Shale trilobites reported f r o m western New York are as follows:
a bundle of limestone bryozoa beds and referred to as the Lewiston Member, and an upper sparsely fossiliferous, d o l o m i t i c shale
Acanthopygc
unit, the Burleigh Hill M e m b e r .
Bumastus
T h e Lewiston M e m b e r has yielded most of the diverse trilo-
Calymene
Arctinurus
sp.
boltoni
Calymene
ioxus
Cheirurus
sp.
niagarensis sp.
bite and e c h i n o d e r m faunas for which the Rochester is justifiably
Dalmanites
famous. Fossils are exceptionally well preserved, especially in beds
Decoroproetus
near the transition from a lower, highly shell-rich interval into a
Diacalymene
middle barren portion of the Lewiston and in the upper transi-
Illaenoides
tion from this sparsely fossiliferous interval to the overlying b r y -
Odontopleurid
Proetid
ozoan-rich beds. T h e s e beds c o n t a i n a n u m b e r of trilobites, s o m e
Radnoria
Staurocephalus
of them in an extraordinary state of preservation. T h e well-
Trimerus
Dalmanites
limulurus corycoeus /.
sp. pisum
Dicranopeltis
sp. cf.
Deiphon
trilobita
sp. delphinocephalus
nereus
Maurotarion
Trochurus
sp. sp. halli
known examples of the large lichid Arctinurus boltoni, as well as abundant
and
T h e R o c h e s t e r Shale seems to reflect siliciclastic muds that were
exquisite
derived from erosion of newly developed highlands to the east or
preservation of s o m e of the fossils suggests that they were buried
southeast. Initiation of this new input is represented through
Trimerus
Dalmanites delphinocephalus,
limulurus, occur
in
Calymene these
levels.
niagarensis, The
instantly by sediment plumes or turbidity currents. T h e Burleigh Hill M e m b e r consists of m e d i u m to dark gray
m u c h o f the Appalachian Basin b y the o c c u r r e n c e o f rather thick sands k n o w n as Keefer S a n d s t o n e in Pennsylvania and
shales with thin calcisiltites, especially toward the top, that grade
the H e r k i m e r S a n d s t o n e in central New York State (Figure 4 . 2 9 ) .
upward into the overlying D e C e w F o r m a t i o n . T h i s upper p o r t i o n
O t h e r circumstantial
evidence suggests
that a new pulse of
THE
90
PALEOZOIC
GEOLOGY
OF
NEW
YORK
tectonic activity o c c u r r e d a b o u t the middle part of the Silurian.
the L o c k p o r t G r o u p c o m e s to rest on the underlying crinoidal
T h i s c o m e s in the f o r m of the shifting of the depositional basin
grainstone o f the I r o n d e q u o i t .
itself. In the t i m e period represented by the W i l l i a m s o n Shale
D u r i n g the Late Silurian a vast c a r b o n a t e bank, somewhat like
to the upper part of the Rochester Shale, the area of thickest
that which existed in the C a m b r o - O r d o v i c i a n , developed o n c e
sediment a c c u m u l a t i o n , d o m i n a n t l y of shale, shifted westward
again in Laurentia. Very widespread shoals were developed from
approximately 100 km from the region of O n e i d a Lake to the area
sand- and gravel-sized skeletal pieces ( m a i n l y columnals) of
of Wayne C o u n t y . T h i s m i g r a t o r y pattern together with the
crinoids and cystoids. Under similar, high-energy environments,
increased input of coarser sediments suggests that renewed thrust
tabulate corals and s t r o m a t o p o r o i d s established reefs in the Great
faulting may have taken place in the f o r m e r T a c o n i c landmass.
Lakes area. A barrier reef c o m p l e x developed around a circular,
Possibly this is the result of new o c e a n - f l o o r s u b d u c t i o n u n d e r -
subsiding a r e a — t h e M i c h i g a n B a s i n — a n d patch reefs developed
neath the eastern margin o f N o r t h A m e r i c a (Figure 4 . 2 9 C ) .
on the tops of crinoidal skeletal shoals from Indiana, to O h i o , and
T h e Rochester Shale represents a relatively shallow but m u d d y -
into New York. M a n y such reefs or b i o h e r m s show a good suc-
b o t t o m sea that ranged upward to over a h u n d r e d meters of water
cession of pioneer thicket formers to climax c o m m u n i t i e s d o m -
depth. T h e Rochester Shale facies grades eastward to the sandy
inated by head corals and s t r o m a t o p o r o i d s . Trilobites were a
shoreline facies of the H e r k i m e r S a n d s t o n e in central New York
m i n o r b u t significant c o m p o n e n t of the reefal faunas.
and to the northwest into c a r b o n a t e banks.
T h e basal L o c k p o r t
unit, G a s p o r t
L i m e s t o n e , consists o f
T h r o u g h o u t m u c h of western New York, the R o c h e s t e r Shale
d o l o m i t i c limestones and s o m e argillaceous dolostone. M u c h o f
is overlain by a rather unusual unit in the D e C e w D o l o s t o n e . T h i s
it can be described as an e c h i n o d e r m packstone or grainstone,
unit is a thin (3 to 5 m) and u n i f o r m interval of b u f f - c o l o r e d
like the underlying I r o n d e q u o i t , that consists of disarticulated
c a r b o n a t e silt with h u m m o c k y cross-stratification. T h e result of
and c o m m o n l y abraded fragments of c r i n o i d and cystoid plates
storm deposition, the D e C e w is also highly convoluted and c o n -
and
torted and in s o m e places displays o v e r t u r n e d folds. We suggest
deposits were m o v e d by s u b m a r i n e currents. Consequently the
columnals.
Typically
these
crinoidal
sands
and
gravel
that this represents a period of seismic s h o c k ( e a r t h q u a k e ) activ-
unit shows m e d i u m - to small-scale cross-stratification (Figure
ity on the floor of the foreland basin or interior continental sea.
4 . 3 2 A ) . S o m e p o r t i o n s o f the Gasport also show bimodal cross-
T h i s effect was widespread; we have f o u n d evidence for a similar
stratification, two opposite o r i e n t a t i o n s of cross-bedding that
d e f o r m a t i o n in D e C e w age strata in central Pennsylvania and
might reflect the influence of oscillating tidal currents. T h e
southern O h i o . Because o f the rapid deposition o f the c a r b o n a t e
Gasport sediments evidently accumulated during a time of initial
silts, this is not a highly fossiliferous unit, although occasional
transgression following a m a j o r regression of seas from western
remains of s o m e fossil crinoids and the trilobite Trimerus have
New York that p r o d u c e d the u n c o n f o r m i t y beneath the unit.
been found within the unit. T h e source o f the D e C e w c a r b o n a t e
D u r i n g a t i m e of rising sea level, b u t still in e n v i r o n m e n t s of
silts and fine sands is s o m e w h a t unclear, but it probably was rep-
shallow, agitated waters, perhaps no m o r e than a few meters deep,
resented by c a r b o n a t e shoals in the f o r m of c r i n o i d gardens that
c r i n o i d banks developed extensively over m u c h of western and
existed to the northwest of the m a i n New York depositional area.
west-central New York. In the Rochester area, these banks appar-
T h e s e shoal facies e n c r o a c h e d u p o n New York d u r i n g the d e p o -
ently interfingered with quartz sand bars represented by the
sition of the succeeding L o c k p o r t G r o u p .
Penfield F o r m a t i o n . T h e s e cross-stratified dolomitic sandstone
An eastern shaly facies equivalent to the DeCew, the G l e n m a r k
units seem to reflect the input of quartzose sediment from a
Shale, yields a diverse fauna of small rugose corals, b r a c h i o p o d s ,
n o r t h e r n or northeasterly source terrain. T h e y form an elongate
and trilobite genera, including Daltnanites sp.,
shoal or barlike feature that extended southward from Rochester
Trimerus, Encrin-
urus sp., calymenid, Maurotarion sp., Cheirurus sp., and proetids.
to the subsurface of New York State. To the east of this area, in Wayne C o u n t y , the sands give way to m u d d y dolostones and d o l o m i t i c limestones, m a n y o f t h e m containing remains o f ostra-
Lockport Group T h e L o c k p o r t G r o u p is an interval over 65 m thick of pre-
cods, s o m e stromatolites, and the trilobite genera Trimerus, Caly-
d o m i n a t e l y d o l o m i t i c c a r b o n a t e rocks. However, to the east of the
mene, Encrinurus, and Maurotarion.
Rochester
Still farther to the east, these
limestones
interfinger with dark gray shale of the Ilion F o r m a t i o n . W i t h i n
interfinger with dark gray shales of the Ilion F o r m a t i o n . In the
the upper part of the Gasport F o r m a t i o n , deepening produced
central Appalachians the L o c k p o r t G r o u p is represented by a
a c h a n g e in s e d i m e n t a t i o n patterns, in western New York, to
d o m i n a n t l y dark, shaly interval with thin r i b b o n - l i k e limestones
t h i n n e r - b e d d e d , m o r e argillaceous dolostones. At the same t i m e ,
termed
small patch reefs, which had begun developing on the now-
area,
the
these
Mackenzie
dolostones
Formation.
and
The
dolomitic
Lockport
represents
a
depositional s e q u e n c e . It is b o u n d e d at its base by a m a j o r erosion
stabilized surface of the crinoidal shoals, built upward, f o r m i n g
surface that locally cuts into the D e C e w D o l o s t o n e and removes
the famed G a s p o r t reefs or b i o h e r m s (Figure 4 . 3 2 B ) . T h e s e reefs
it in areas near H a m i l t o n , O n t a r i o , where the u n c o n f o r m i t y c o n -
were built primarily of favositid corals and stromatoporoids. T h e
tinues to cut d o w n w a r d into the Rochester Shale until the base of
G a s p o r t is not particularly n o t e d for trilobites, although s o m e
FIGURE 4 . 3 1 . M i d Silurian s u c c e s s i o n s . A. Lowest light limestone l e d g e , Irondequoit L i m e s t o n e (a) is overlain by about 20 m of dark gray Rochester Shale (b). Thick layers of the L o c k p o r t G r o u p (c) protrude at the t o p of the cliff. Niagara River G o r g e , south of L e w i s t o n - Q u e e n s t o n B r i d g e , N i a g a r a County. B. Lowest rhythmic thin b e d s are Rockway Formation (a). These are sharply overlain by Irondequoit Limestone (b) b e a r i n g small b i o h e r m s ("reefs") (arrow) that protrude slightly into the overlying Rochester Shale (c). G e n e s e e River G o r g e , Rochester, Monroe County.
FIGURE 4.32. Silurian c a r b o n a t e s . A. C r o s s - b e d d e d crinoidal limestone, G a s p o r t Formation, cut along Robert M o s e s Parkway, Lewiston, N i a g a r a County. B. B i o h e r m or reef m o u n d of s t r o m a t o p o r o i d s a n d tabulate corals, Goat Island Formation, overlies t h i n - b e d d e d u p p e r G a s p o r t Formation on the right e n d of the cut. Road cut on Rte. 429, N i a g a r a e s c a r p m e n t , Pekin, N i a g a r a County.
SILURIAN
93
PERIOD
specimens of calymenids are f o u n d . An area of interfingering
dolostones are characterized by small thickets or biostromes of
(shaly)
grainstones
corals, especially c l a d o p o r i d s . T h e y represent thickets of small
occurs in the Sweden-Walker Q u a r r y at B r o c k p o r t , M o n r o e
tabulates and o t h e r corals that grew in shallow waters. S t r o m a t o -
County. This transitional facies has yielded the r e m a i n s of
poroids are also c o m m o n as isolated heads within these beds, typ-
dolostones with
Dalmanites,
Trimerus,
and
typical
another
Gasport
rare
crinoid
homalonotid
trilobite.
ically up to a foot across b u t highly altered by diagenesis. T h e s e
Also, s o m e of the b i o h e r m a l faunas have yielded f r a g m e n t a r y
beds, like the underlying G o a t Island, are typically vuggy and
remains of the calymenid, Diacalymene, and o t h e r trilobites.
c o n t a i n a b u n d a n t mineralized pockets that are well known to
T h e overlying G o a t Island F o r m a t i o n is separated in most
local mineralogists. In O n t a r i o , C a n a d a , however, the basal beds
places from the Gasport by a m i n o r u n c o n f o r m i t y . It represents
of the E r a m o s a that overlie E r a m o s a Shales and appear almost
the second cycle of shallowing, followed by deepening and the
gradational into the latter, are platy argillaceous dolostones that
development of crinoidal shoals and in places such as at B r o c k -
seem to represent s o m e w h a t m o r e offshore c a r b o n a t e a c c u m u l a -
port, the development of small patch reefs of s t r o m a t o p o r o i d s
t i o n . T h e s e basal E r a m o s a c a r b o n a t e s are n o t e d for abundant,
and corals (Figure 4 . 3 1 B ) . T h e s e reefs have m a n y features in
although m a i n l y disarticulated, trilobites. Q u a r r i e s in the vicin-
c o m m o n with the underlying G a s p o r t . However, in m a n y places,
ity o f D u n d a s , O n t a r i o , have yielded t h o u s a n d s o f specimens o f
the G o a t Island has been affected severely by late diagenetic
the otherwise rare trilobite Encrinurus raybesti, along with caly-
dolomitization, which has altered its texture and m a d e it difficult
m e n i d s , and a new d a l m a n i t i d species. T h e E r a m o s a represents
to decipher the original fossil content and o t h e r features.
a return to c o n d i t i o n s s o m e w h a t m o r e like those of the Rochester
An argillaceous d o l o s t o n e bed near the base of the G o a t
Shale, although pulses of rapid burial were rare in the E r a m o s a ;
Island, however, has yielded an e x t r a o r d i n a r y biota of s o f t - b o d i e d
hence, most
trilobites
are disarticulated.
In
New York and
organisms, particularly algae, s o m e w o r m s , and graptolites. T h i s
t h r o u g h o u t at least the eastern Niagara Peninsula of O n t a r i o , the
deposit, which L o D u c a ( 1 9 9 5 ) studied extensively, appears to rep-
upper beds of the E r a m o s a reflect an abrupt shallowing. Layers
resent an a c c u m u l a t i o n of muds in shallow waters between patch
o f stromatolites o r bacterial mat b o u n d s t o n e s were c o m m o n and
reefs in the G o a t Island F o r m a t i o n . Unfortunately, to date, it has
widespread at this t i m e . T h e s e stromatolites f o r m e d d o m a l heads
yielded few, if any, trilobite remains.
up to 2 or 3 m across and a m e t e r tall (Figure 4 . 3 3 ) . T h e s t r o m a -
T h e upper Goat Island in western New York, and particularly
tolites are generally associated with a sparse low diversity of
been
favositid corals, o s t r a c o d s , and a few species of b r a c h i o p o d s . T h e
misidentified as the E r a m o s a F o r m a t i o n . It is presently t e r m e d
i n c o m i n g of these beds appears to reflect the stress of increased
in
O n t a r i o , is
highly argillaceous and
frequently has
the Vinemount Shale Member. V i n e m o u n t Shale beds have yielded
hypersalinity in the Appalachian Basin. To the east, beds of the
several fragmentary fossil r e m a i n s , including trilobites, small
S c o n o n d o a and upper Ilion reflect these s a m e sorts of changes.
rugose corals, and b r a c h i o p o d s , although the extensive d o l o m i t i -
S t r o m a t o l i t i c limestones give way abruptly eastward to dark
zation of these argillaceous c a r b o n a t e s has o b s c u r e d m o s t of the
shales c o n t a i n i n g few n o r m a l m a r i n e o r g a n i s m s but remains o f lingulid b r a c h i o p o d s and eurypterids. T h e s e in turn pass upward
details. Near Ancaster, O n t a r i o , and locally in Niagara C o u n t y , New York, an upper portion of the G o a t Island yields white chert nodules that contain the remains of n u m e r o u s species of fossils
to the red beds of the V e r n o n F o r m a t i o n . Although not generally considered a trilobite-rich interval, the L o c k p o r t G r o u p in total has yielded the following trilobites:
in a rather g o o d state of preservation. Particularly notable are small siliceous sponges that may hint at the source for the silica of the light-colored cherts. Also, a variety of b r a c h i o p o d s and several trilobite species, including calymenids and dalmanitids, have been obtained as fragments f r o m these chert nodules. Evidently, early replacement by silica protected fossils f r o m d o l o m i tization, thereby leaving a reasonable record of these fossils.
Calymene
singularis
Calymene
Dalmanites
sp.
Diacalymene
sp.
Maurotarion
sp.
Encrinurus Proetus Scutellum
raybesti artiaxis wardi
Proetus Trimerus
sp.
tenuisulcatus delphinocephalus
Howell and Sanford ( 1 9 4 7 ) described trilobites from the G o a t Island
Formation
(formerly
misidentified
as
Oak
Orchard
M e m b e r ) in the Rochester area:
Late Silurian Salina G r o u p
Calymene Proetus
singularis artiaxis
Encrinurus
sp.
Scutellum
wardi
D u r i n g the Late Silurian, a m o r e arid climate prevailed over eastern Laurentia, and a landlocking of seas o c c u r r e d in two areas. T h e later part of the Silurian in eastern N o r t h America is
T h e Eramosa F o r m a t i o n is represented over m o s t of central and
represented by the Salina G r o u p . As the n a m e implies, these
western New York by vuggy, massive dolostones that have c o m -
deposits represent a m i x t u r e of s o m e shales and dolostones but
m o n l y been termed Oak Orchard Formation
are primarily n o t e d for evaporites. In the M i c h i g a n Basin, the
in the past. T h e s e
94
THE
PALEOZOIC
GEOLOGY
OF
NEW
YORK
FIGURE 4 . 3 3 . Domal stromatolites (arrow). Guelph Dolostone, Robert M o s e s Power Plant a c c e s s road, Lewiston, Niagara County.
barrier reef c o m p l e x restricted circulation, while in the eastern
ite beds within the Vernon reflects restriction of the Appalachian
Appalachian region, a new pulse of s e d i m e n t s eroded o f f coastal
Basin. T h e Vernon clastic sediments appear to represent a final
m o u n t a i n s . T h e V e r n o n - B l o o m s b u r g d e l t a — w a s derived f r o m
pulse of elastics derived f r o m erosion of the newly uplifted m o u n -
Salinic O r o g e n i c uplifts southeast (present directions) of New
tainous source terrain to the southeast of New York State. In
York State. T h e outward building ( p r o g r a d a t i o n ) o f the V e r n o n -
Pennsylvania, extremely thick red mudstones of the B l o o m s b u r g
B l o o m s b u r g delta
a
Shale take the place of the Vernon and seem to point to a nearby
partial barrier to o c e a n i c circulation in the n o r t h e r n Appalachian
source of m u d s and silts. North America at this time appears to
Basin of New York. T h e s e restrictive barriers prevented o p e n cir-
have lain within the subtropical desert belt, probably in paleolat-
culation to the sea and enabled salinity to build up to the p o i n t
itudes between 20 and 30° south of the equator (Figure 4 . 5 ) .
into
south-central
Pennsylvania
formed
of precipitating evaporites. A cyclic process of seawater influx
U n d e r such c i r c u m s t a n c e s , the development of a large wedge of
then evaporation enabled evaporites, such as anhydrite, g y p s u m ,
deltaic m u d s t o n e s and sandstones in the B l o o m s b u r g / V e r n o n
and halite, to a c c u m u l a t e to considerable thickness. T h e salt layer
F o r m a t i o n produced a restriction in the circulation in the n o r t h -
under Detroit, M i c h i g a n , is over 1 km thick.
ern Appalachian Basin region. T h i s restricted circulation in c o m -
T h e Upper Silurian V e r n o n F o r m a t i o n consists o f probably
b i n a t i o n with the arid climate led to the development of a
n o n m a r i n e or very shallow tidal-flat deposits of a red, rather
hypersaline seaway, probably similar in s o m e ways to the m o d e r n
massive m u d s t o n e . T h e s e beds c o n t a i n few fossils, although an
D e a d Sea. As seawater evaporated away, salt and anhydrite or
occasional interbedded d o l o s t o n e yields remains of fossil jawless,
gypsum deposits began to a c c u m u l a t e in the lower sags of the
a r m o r e d fish. Small clams and b r a c h i o p o d s also m a y be present
basin, while on the margins s o m e , at least seasonal, input of
in these beds. To the west the Vernon gives way from red m u d -
siliciclastic m u d s c o n t i n u e d .
stones to greenish gray d o l o m i t i c shales a n d d o l o s t o n e s , m a n y of
Although salt deposition o c c u r r e d within the western New
which contain evaporite crystal m o l d s . T h e V e r n o n in western
York/Genesee Valley region during deposition of the Vernon
New York is probably m o s t n o t e d as the source of key salt beds
Shales at the base of the Salina G r o u p , the locus of salt deposi-
that have been m i n e d for m a n y decades at the R e t s o f M i n e s in
tion
the area of the Genesee Valley. T h e a p p e a r a n c e of these evapor-
the Salina G r o u p sediments. T h i s eastward shifting also may
shifted progressively eastward during the deposition
of
DEVONIAN
PERIOD
have been associated with the m i n o r uplift of the old Vernon/
95 position (Figure 4 . 3 6 A ) . O n l y a few species of normal marine
B l o o m s b u r g deltaic land above sea level, which p r o d u c e d an e r o -
fossils are f o u n d within parts of the Bertie. T h e y include lingulid
sional beveling of Late to Middle Silurian sediments in areas east
b r a c h i o p o d s , a few o t h e r species of articulate b r a c h i o p o d s , and
of Utica, O n e i d a County. A large salt depositional basin existed
a
in the central region of the Finger Lakes and eventually in the
cephalopods).
classic Syracuse area. T h e s e deposits, the Syracuse F o r m a t i o n ,
e n o u g h that n o r m a l m a r i n e c o m m u n i t i e s still were not estab-
take their n a m e from that city. T h e f o r m a t i o n consists of thin-
lished in the offshore areas.
few
species
of
mollusks
(snails,
clams,
and
orthoconic
Evidently, salinity remained high and variable
bedded dolostones and shales and in places thick a c c u m u l a t i o n s
A new, unusual trilobite, apparently a lichid, was recently
of anhydrite or salt. Although the remains of n o r m a l m a r i n e
collected f r o m the e u r y p t e r i d - b e a r i n g waterlimes in Fort Erie,
organisms are u n c o m m o n within these beds, there are stray
O n t a r i o , near Buffalo. On the whole t h o u g h , these beds reflect
reports o f s o m e b r a c h i o p o d s and even o f o n e o c c u r r e n c e o f a
unusual hypersaline c o n d i t i o n s , and trilobites are very rare.
trilobite, a calymenid, within the Syracuse F o r m a t i o n in the Syra-
However, finally within the latest part of the Silurian, normal
cuse area. O t h e r w i s e , c o n d i t i o n s generally were far t o o harsh,
m a r i n e c o n d i t i o n s returned over New York, Pennsylvania, and
owing to the elevated salinity, to s u p p o r t n o r m a l m a r i n e c o m -
m u c h o f the Appalachian Basin. T h e Keyser F o r m a t i o n o f Penn-
munities, and most o f the beds o f the Salina G r o u p are barren o f
sylvania and the laterally equivalent R o n d o u t G r o u p and Decker
fossils. M o r e diverse m a r i n e fossils, including c a l y m e n i d trilo-
F o r m a t i o n in New York State c o n t a i n a far m o r e diverse assem-
bites, are k n o w n from the laterally equivalent Tonoloway F o r m a -
blage of m a r i n e fossils than do the underlying Bertie and Salina
tion in Pennsylvania, M a r y l a n d , and West Virginia.
beds. At least d u r i n g times of the deposition of the R o n d o u t ,
Salina deposition was terminated by the a c c u m u l a t i o n of the
shallow marine c o n d i t i o n s rather akin to those that developed
Camillus F o r m a t i o n , a relatively thick interval of m o t t l e d gray to
during the L o c k p o r t deposition existed over p o r t i o n s of eastern
slightly reddish barren shales with salt crystal molds and s o m e
and central New York State. At times, units such as the Cobleskill
dolostones, c o m m o n l y with molds of small gypsum or anhydrite
L i m e s t o n e a c c u m u l a t e d with a b u n d a n t c r i n o i d , coral, s t r o m a t o -
lathlike crystals. Not surprisingly, the Camillus is nearly barren of
poroid, and o t h e r remains. Trilobites are scarce but are repre-
fossils. It too has served as a source for e c o n o m i c a l l y i m p o r t a n t
sented
gypsum deposits in western New York.
camerata,
Hedstroemia
Dalmanites
aspinosus.
Bertie D o l o s t o n e and R o n d o u t G r o u p During the very late phases of Silurian deposition in New York
by
a
fair
diversity
of species
pachydermata, In
such
Richtcrarges
Pennsylvania
the
as
the
Calymene
ptyonurus,
laterally
and
equivalent
Keyser F o r m a t i o n c o n t a i n s small reef buildups of corals and strom a t o p o r o i d s and o t h e r shaly beds, rather reminiscent of the
State, the Bertie G r o u p sediments a c c u m u l a t e d . T h e Bertie is an
m u c h older Rochester Shale, that c o n t a i n diverse bryozoan and
unusual rock unit that consists of argillaceous, b u f f - c o l o r e d d o l o -
b r a c h i o p o d faunas and a b u n d a n t , well-preserved cystoids. Again,
stone, referred to in the past as waterlimes because of their p r o p -
s o m e trilobites are reported f r o m these Keyser beds. Preservation
erty as natural cement r o c k s , yielding c e m e n t s , which hardened
within the Keyser ranges f r o m disarticulated to exquisite arti-
underwater. T h e Bertie, as with the underlying Salina G r o u p , c o n -
culated remains. T h u s , the last chapter of Silurian m a r i n e de-
tains m u c h evidence for deposition at or near sea level. W i t h i n
position records a b r e a k d o w n of barriers to n o r m a l marine
the f o r m a t i o n are beds of low d o m a l stromatolites, extensive
circulation, as well as possible climatic changes from the m o r e
layers of fine, m u d - c r a c k e d d o l o s t o n e , gypsum crystal m o l d s ,
arid c o n d i t i o n s that characterized deposition of the Salina and
very shallow water ripples, and o t h e r evidence for deposition in
Bertie
a restricted tidal flat to shallow lagoonal setting. T h e Bertie is
Appalachian Basin, so t o o did n o r m a l m a r i n e representatives,
most noted for its extraordinary eurypterids at certain horizons.
which must have i m m i g r a t e d in f r o m outside the basin.
Groups.
As
normal
marine
seas
returned
to
the
T h e e n v i r o n m e n t of these interesting c h e l i c e r a t e a r t h r o p o d s is still debatable. Although they are often preserved in rocks that contain evidence for hypersalinity, such as salt crystal casts, the
Devonian Period
eurypterids probably did not live under these highly saline c o n -
T h e Devonian Period ( 4 1 5 to 3 6 0 million years ago) was
ditions. Rather, the local heavy a c c u m u l a t i o n s of carcasses of
relatively long, with m a n y i m p o r t a n t events in Earth and life
these animals probably represent dead remains that were washed
history (Figure 4 . 1 ) . M a j o r orogenies took place in Europe (end
out from estuaries that fed into the m o r e saline Bertie sea; c a r -
of C a l e d o n i a n ) , eastern N o r t h A m e r i c a ( A c a d i a n ) , and for the
casses were rapidly buried in briney sediments. T h e a p p e a r a n c e
first t i m e in the P h a n e r o z o i c , western North America (Antler
of small land plants, s o m e of the oldest k n o w n in the world, along
O r o g e n y ) (Figure 4 . 3 4 ) . M u c h o f the Devonian was characterized
with the eurypterids suggests that these sediments a c c u m u l a t e d
by w a r m , " g r e e n h o u s e " - t y p e climates and a strong tendency for
in very close proximity to low-lying lands of the upper tidal flats
stagnation in deeper sea e n v i r o n m e n t s , leading to the f o r m a -
and probably in small estuaries that e m a n a t e d o f f the exposed
tion of very widespread a n o x i c (oxygen-deprived) black shale
land that were, at least periodically, brackish water in their c o m -
deposits (Figure 4 . 3 5 ) . However, toward the end of the period
96
THE
PALEOZOIC
GEOLOGY
OF
NEW
YORK
FIGURE 4.34. C o m p o s i t e stratigraphic chart for the northern a n d central parts of the A p p a l a c h i a n Basin, s h o w i n g the depositional s e q u e n c e s a n d their relationship to t e c t o p h a s e s . From Ettensohn (1987), © 1987 by the University of C h i c a g o . All rights r e s e r v e d . R e p r o d u c e d with p e r m i s s i o n . there is evidence for climatic stress associated with renewed
lying Tristates groups, including the m o r e offshore facies, are c o n -
glaciation in G o n d w a n a (especially S o u t h A m e r i c a ) .
fined to the Hudson River Valley and probably o n c e extended northeastward into New England and Q u e b e c .
Early Devonian T h e Lower D e v o n i a n rocks of New York State are represented primarily by the Helderberg a n d Tristates G r o u p s . T h e final,
Late Early Devonian H e l d e r b e r g Facies and Trilobites
regressive phases of Sloss's T i p p e c a n o e (Tutelo phase) Superse-
T h e lowest unit of the Helderberg G r o u p is the T h a c h e r
quence are recorded in the Helderberg c a r b o n a t e s of eastern New
M e m b e r o f the M a n l i u s F o r m a t i o n (Figure 4 . 3 5 C ) . However, the
York and Pennsylvania (Figure 4 . 3 5 ) . T h e Helderberg G r o u p is
M a n l i u s facies are distinctly d i a c h r o n o u s , being younger in the
a series of limestones and m i n o r shales that c r o p out in central
area near Syracuse, New York, than in the Hudson Valley and
to eastern New York State. O u t s t a n d i n g exposures of these rocks
equivalent in age to the C o e y m a n s or even Kalkberg F o r m a t i o n s
are cuts along Rte. 1-88 in the S c h o h a r i e Valley, and a n u m b e r of
in the H u d s o n Valley. T h e M a n l i u s is considered to be close to the
quarries and road cuts from the area of Albany, at the Helderberg
S i l u r i a n - D e v o n i a n b o u n d a r y (Rickard 1 9 7 5 , 1 9 8 1 ; K l a p p e r 1 9 8 1 ) .
E s c a r p m e n t , southward to the state line at Port Jervis, O r a n g e County.
T h e M a n l i u s F o r m a t i o n bears m a n y resemblances to the O r d o v i c i a n Black River G r o u p . B o t h intervals contain a series of
It should be noted that d u r i n g Helderberg deposition, the axis
peritidal to very shallow subtidal facies. T h e Manlius represents
(deepest part) of the Appalachian Basin was at a position s u b -
the belt of low-energy but very shallow lagoonal to tidal-fiat envi-
stantially farther east than d u r i n g Silurian or later Devonian
r o n m e n t s that were sheltered to shoreward by offshore shoals and
t i m e . T h e basin axis appears to have shifted eastward d u r i n g a
bars. T h i s suite o f e n v i r o n m e n t s has been called the " Z " zone
t i m e of tectonic quiescence b e g i n n i n g in the late part of the
(Irwin 1 9 6 5 ) . T h e s e facies typically are arranged in 1- to 3 - m
Silurian, and to have been in a position east of the H u d s o n Valley
scale, shallowing-upward cycles referred to as punctuated aggra-
extending northeastward into New England at this p o i n t in Early
dational cycles (PACs)
D e v o n i a n t i m e . For this reason, m o s t of the Helderberg and over-
cyclic facies are typical of the older T h a c h e r M e m b e r of the
( G o o d w i n and Anderson
1 9 8 5 ) . Such
I Acadian O r o g e n y - Collision of Avalon and P r o t o North A m e r i c a
<- N Y - t
Auburn
Syracuse
Richfield Springs
L'Qca
Schoharie
Albany
CauJall
Legend DolomuK f»c*» •J Mienoc hoes ^| Bujirroroe [iciei
,
Skfieal pKluwn* piuwone ficies £3 fKaam-caiarwau wale ton Sh»kr *«c*«kdi» tam A
g ? l B«6tm>
—
— i
:
A
'' .
•
- L
~~
**
~"-i
= ^ Roodout
. ^ 1 ^ 5
* ""'
— ~
,
• = ~— -
a
l
r
" - ^ ^ Kalkberg^-'
-
- * » i i p j ^ - ^ - ^ g = = jf
-
^.PonJ-wcn
~ - ^ - ^ ^ " ^ " ^ F ^ Sevi
Scotland-j
.
^^^^^^^^^^^^^^^^^
tr~3
FIGURE 4.35. New York d u r i n g the Early D e v o n i a n . A. M a p of the state d u r i n g this time. B. Cross section of the A c a d i a n Orogeny. C. Stratigraphic chart of the Early D e v o n i a n . B, C from Isachson et al. (1991). Printed with permission from the New York State M u s e u m , Albany, N.Y
THE
98 Manlius in the H u d s o n Valley. T h e typical M a n l i u s cycle begins
PALEOZOIC
GEOLOGY
OF
NEW
YORK
Jerusalem Hill area, H e r k i m e r C o u n t y , just east of Utica, Dal-
with s o m e w h a t nodular, m e d i u m gray, b i o t u r b a t e d l i m e s t o n e ,
manites
c o m m o n l y with
tabu-
material is disarticulated, although rare articulated specimens are
late corals. Fragments of a variety of o t h e r fossils, including gas-
k n o w n . T h e Ravenna M e m b e r represents a high-energy shoal
t r o p o d s , nautiloids, s o m e b r a c h i o p o d s , and ostracodes, may be
e n v i r o n m e n t , c o m p a r a b l e in m a n y ways to the older Silurian
present. Such beds may be transitional into thin platy limestones
Gasport F o r m a t i o n , Irondequoit L i m e s t o n e , or other similar
that often have been referred to as " r i b b o n l i m e s t o n e s " and may
units. In the traditional m o d e l of X, Y, and Z zones (a low-,
contain rather well-preserved fossils on s o m e bedding planes. For
high-, low-energy profile) associated with an offshore shoal, the
example,
C o e y m a n s represents Y-zone (high-energy) facies. As such, it
a b u n d a n t s t r o m a t o p o r o i d s and
famous
outcrops
near
Litchfield,
some
New York,
have
litchfieldensis
and
Odontochile
micrurus
are
found.
Most
yielded bedding planes with a b u n d a n t well-preserved crinoids
is t h o u g h t that the C o e y m a n s shoal-like e n v i r o n m e n t s sheltered
and s o m e cystoids ( G o l d r i n g 1 9 2 3 ) . Trilobites, o t h e r than Odon-
the low-energy belt in which Manlius fine-grained carbonates
tochile micrurus, tend to be very rare in these facies. Shallower
a c c u m u l a t e d in a series of low-energy lagoons and tidal flats.
water p o r t i o n s of the M a n l i u s consist of planar to wavy laminated
T h e C o e y m a n s grainstone grades upward into the Kalkberg
micritic limestones that display a regular, even slightly wavy l a m -
and New Scotland shaly limestones. T h e s e intervals are typically
ination. A regular alternation of thicker coarser and finer t h i n n e r
c o m p o s e d of finer-grained c a r b o n a t e muds and silts, with s o m e
laminae suggests that they have a c c u m u l a t e d under the influence
thin shaly intervals. Fossils are moderately to highly abundant,
of tidal currents. T h e waviness of l a m i n a t i o n within these facies
although typically not m a k i n g up the m a j o r c o m p o n e n t of these
suggests that thin bacterial mats m a y be responsible for s o m e of
rocks, in contrast to the C o e y m a n s skeletal limestone. T h e lower
the trapping of sediment deposited f r o m e b b i n g tidal currents.
Kalkberg ( H a n n a c r o i x ) M e m b e r is typified by a series of black
H e n c e , these l a m i n a t i o n s are s o m e t i m e referred to as " c r y p t a l g a l "
chert beds, each a b o u t 10 cm thick, which have been traced later-
or tidal laminites. T h i s facies is generally sparsely fossiliferous.
ally in the H u d s o n Valley. T h e unit is notable for a fauna of b r a -
However, occasional thin layers or b e d d i n g planes, s o m e repre-
c h i o p o d s , b r y o z o a n s , and p e l m a t o z o a n fragments. T h e upper
senting hard grounds (early c e m e n t e d seafloors), do display small
Kalkberg and p o r t i o n s of the New Scotland are typically s o m e -
fossils such as ostracodes, Tentaculites, m i n o r b r y o z o a n s , small
what darker gray, shaly limestones that display a banded appear-
bivalves, and edrioasteroids. Again trilobites tend to be very rare
ance o f alternating 2 0 - t o 3 0 - c m - t h i c k , b u f f and gray bands. T h e
in these facies.
b u f f b a n d s are s o m e w h a t d o l o m i t i c limestones, typically rich in
Finally, the shallowest facies of the M a n l i u s c o m p r i s e thinly
b r a c h i o p o d shells, whereas the darker gray bands are c o m p o s e d
bedded, s o m e t i m e s shaly d o l o m i t i c limestones, often with m a j o r
of shale, often with a b u n d a n t fossil fragments and s o m e m i n o r
desiccation cracks that may e x t e n d d o w n w a r d into the rock,
phosphatic pebbles. Beds of w i n n o w e d skeletal hash in the Kalk-
f o r m i n g polygonal prismatic c o l u m n s as m u c h as 5 0 c m into the
berg, however, suggest the influence of storm-wave deposition at
section
times.
(Figure
4.36A).
These
mudcracked
facies
represent
supratidal e n v i r o n m e n t s ( a c c u m u l a t i o n above m e a n high-tide level).
T h e New Scotland shaly limestone appears to represent a c u l m i n a t i o n of a deepening cycle. T h e New Scotland may be
T h e M a n l i u s F o r m a t i o n extends the farthest west o f any o f
c o m p a r e d in s o m e ways to the older Rochester Shale facies in
the Helderberg units, being f o u n d in considerable thickness in the
the Silurian. Like the R o c h e s t e r it represents an area close to the
vicinity of Syracuse and extending as a thin feather edge westward
lower effects of s t o r m waves ( c o m m o n l y referred to in the Irwin
to Cayuga Lake. However, p o r t i o n s of the M a n l i u s are probably
M o d e l of facies as the "X z o n e " ) . T h e New Scotland is a calcare-
age equivalent to s o m e of the middle p o r t i o n of the Helderberg
ous m u d s t o n e and argillaceous limestone. It is highly fossilifer-
G r o u p farther east. T h e upper M a n l i u s Olney, Jamesville, and
ous in s o m e beds and m o r e sparsely fossiliferous elsewhere. T h e
Pools B r o o k m e m b e r s in the Syracuse area are the shallow-water
New Scotland is rich in b r a c h i o p o d s , bryozoans, and mollusks
equivalents of the middle Helderberg beds and represent a m a r -
and carries a fairly diversified trilobite fauna. In c o m m o n with
ginal m a r i n e , c a r b o n a t e m u d - f l a t to lagoonal e n v i r o n m e n t that
the Silurian R o c h e s t e r Shale, these deeper-water facies in the D e v o n i a n appear to be d o m i n a t e d by dalmanitid trilobites such
existed on the northwest side of the Appalachian Basin. In the Hudson Valley and S c h o h a r i e regions, the M a n l i u s is
as
Dalmanites
pleuroptyx,
Neoprobilium
nasutus,
and
N.
tridens.
sharply overlain by the C o e y m a n s ( R a v e n n a ) M e m b e r . To the
A m o r e c o m p l e t e listing of the K a l k b e r g - N e w Scotland trilobites
west, C o e y m a n s appears to intertongue and grade into M a n l i u s
is as follows:
facies in the vicinity of Herkimer, H e r k i m e r C o u n t y , or Utica. T h e Ravenna
Member
is
best
developed
in
the
Hudson
Valley
and consists o f rather coarse-grained skeletal limestone c o m -
Acanthopyge
posed m a i n l y o f ossicles o f crinoids and the unusual cystoid
Dalmanites
Lepocrinites.
It
also
contains
pentamerid brachiopods
the
remains
of
(Lobopyge)
Cordania
cyclurus
consanquinea
robust
shelled
Gerastos
(Gypidida), b u t few trilobites.
In the
Kettneraspis
pleuroptyx protuberans sp.
Dicranurus
hamatus
Kettneraspis
tuberculata
Neoprobilium
nasutus
FIGURE 4.36. U p p e r Silurian/Lower Devonian rocks. A. M u d c r a c k p o l y g o n s in the U p p e r Silurian Salina G r o u p (Wills Creek Formation), near C u m b e r l a n d , M a r y l a n d . B. Lower D e v o n i a n , u p p e r H e l d e r b e r g G r o u p . Lowest white b e d s are Becraft crinoidal limestone (a). These are overlain by m e d i u m gray Alsen Formation (b) a n d the latter, by dark to light gray Port Ewen Formation (c). Note the anticline (fold) f o r m e d d u r i n g the A c a d i a n Orogeny. Rte. 199 north of Kingston, Ulster County.
100
THE
Neoprobiliutn tridens
Oinochoe
Oinochoe pustulosus Scutellum
Paciphacops
from
bigsbyi
PALEOZOIC
overlying
Kaskaskia
GEOLOGY
OF
Supersequence.
NEW
YORK
T h e higher Lower
D e v o n i a n strata are assigned to the Tristates G r o u p and c o m -
logani
prise quartzose sandstones, dark gray mudstones and inter-
pompilius
bedded calcareous m u d s t o n e s , and silty argillaceous siltstones T h e top of the New Scotland is m a r k e d by the abrupt return
(Rickard 1 9 6 2 , 1 9 7 5 ) . T h e early phase of sea-level rise resulted in
to shallower-water facies. T h e unit is overlain by pinkish gray
deposition of basal transgressive quartz sandstones (Oriskany)
crinoidal grainstone referred to as the Becraft Limestone. T h i s unit
analogous
bears s o m e resemblance to the older C o e y m a n s F o r m a t i o n , al-
4 . 1 ) — t h e Oriskany sandstones and equivalent limestones, an
though it is a m o r e thoroughly crystalline (well-washed c r i n o i d
o r t h o q u a r t z i t e - c a r b o n a t e s u i t e — b u t these give way to mixed
g r a i n s t o n e ) , pinkish gray l i m e s t o n e , typically with green shale
shales and c a r b o n a t e s .
partings near the base. T h e unit also is c o m p o s e d mainly of crinoidal fragments including the strange, disk-shaped shields,
to
Potsdam
(Sauk
S o m e uncertainties remain
Supersequence;
see
Figure
about the positions o f conti-
nents. G o n d w a n a l a n d was apparently getting close to E u r a m e r -
referred to as Aspidocrinus, which are t h o u g h t to be a type of h o l d -
ica. Laurentia still sat on the paleoequator, though it had rotated
fast or a t t a c h m e n t structure of crinoids. T h e b r a c h i o p o d Gypidula
slightly f r o m its earlier position. T h e present east side was south
occurs in this unit, as it does in the C o e y m a n s , although is repre-
of the equator, the northwest in the d o l d r u m s , while Alaska and
sented by a different species. T h e Becraft represents the return of
Arctic C a n a d a developed reefs and evaporites in the northern
shallow, high-energy shoal c o n d i t i o n s . T h e s e e n v i r o n m e n t s do not
subtropics.
appear to have been highly favorable to the growth or preservation of trilobites; very few have been reported f r o m this unit.
In
Europe
the
Caledonian
Orogeny continued
from
the
Silurian and caused m a j o r folding and thrusting in Scandinavia
T h e Becraft L i m e s t o n e is followed by a succession of rocks
and parts of n o r t h e r n Britain. A m a j o r t h e m e for eastern North
that closely m i m i c s that seen in the C o e y m a n s - K a l k b e r g - N e w
A m e r i c a involved the convergence of the s u b c o n t i n e n t of Avalo-
Scotland succession
Helderberg
nia with Laurentia, to p r o d u c e the Acadian O r o g e n y in a series of
G r o u p . T h u s , the Becraft is directly overlain by a s o m e w h a t
o f the lower p o r t i o n o f the
three or four t e c t o p h a s e s (tectonic episodes); each follows a
cherty, fine-grained, buff- and g r a y - b a n d e d l i m e s t o n e , the Alsen
similar pattern (Figures 4 . 3 3 and 4 . 5 D ) .
F o r m a t i o n that strongly resembles the older Kalkberg. T h i s layer
S o m e of the first activity occurs in the Northeast, even during
is followed, in t u r n , by an analog of the New S c o t l a n d , referred
the Helderberg times. T h i n ash beds have been reported in the
to as Port Ewen F o r m a t i o n . T h e Port Ewen is b r o w n i s h gray
Kalkberg, and o n e in particular ( t h e Bald Hill b e n t o n i t e ) in
weathering with distinctive white, podlike, c o n c r e t i o n a r y l i m e -
C h e r r y Valley, O t s e g o C o u n t y , has been dated at approximately
stone layers. T h e s e layers s o m e w h a t resemble the bands of the
4 1 7 million years b e f o r e present. T h e s e ash beds indicate that vol-
New Scotland but are m o r e distinctly lenticular in f o r m . T h e y
c a n i s m was o n g o i n g during the deposition of the Helderberg
appear to represent b u r r o w e d l i m e s t o n e that has u n d e r g o n e
G r o u p . Indeed, in n o r t h e r n M a i n e and the M a r i t i m e Provinces,
s o m e alteration during c o m p a c t i o n and c e m e n t i n g of the sedi-
Helderberg-age
m e n t . T h e Port Ewen and Alsen units also c o n t a i n m u c h the s a m e
developed. However, the first m a j o r effect in the New Y o r k - P e n n -
fauna
sylvania area is reflected by the development of the Tristates
as
the
Kalkberg-New
Scotland
succession,
including
familiar bryozoans, b r a c h i o p o d s , and the d a l m a n i t i d trilobites.
(Lower
Devonian)
volcanics
are
rather well
Group.
However, the latter are less c o m m o n in the Port Ewen than in the
Avalonia attached to the outer side of Laurentia through a
New Scotland. Overall, the Port Ewen c o n t a i n s a substantial
suture or line of c o n t a c t , in central England (southern England
a m o u n t of sparsely fossiliferous, although
heavily b u r r o w e d ,
muddy limestone and calcareous m u d s t o n e .
is part of Avalonia, Scotland is part of Laurentia), producing the Acadian O r o g e n y (Figure 4 . 5 ) . Eastern Newfoundland (Avalon
T h e highest unit of the Helderberg G r o u p , the Port Jervis F o r -
Peninsula) was welded to western Newfoundland, and the eastern
m a t i o n , is only exposed in a n a r r o w region of southeastern New
Massachusetts area was added to Laurentia. Effects of the Acadian
York near the state line at Port Jervis, and in a small isolated
O r o g e n y are evident t h r o u g h o u t New England and the M a r i t i m e
o u t c r o p belt referred to as the Skunnemunk Outlier. Port Jervis is
Provinces; s u b d u c t i o n of the Avalonian plate westward under the
somewhat argillaceous l i m e s t o n e , similar to the New S c o t l a n d ,
old T a c o n i c land of New England created a new m a g m a t i c arc
but it is noted particularly for an a b u n d a n c e of trilobites. Indeed,
(Figure 4 . 3 5 B ) . M a n y o f the granite and gneiss d o m e s o f New
a landmark in the Port Jervis area is called " T r i l o b i t e M o u n t a i n , "
H a m p s h i r e ( t h e " G r a n i t e S t a t e " ) , as well as those of the Acadia
n a m e d for the a b u n d a n c e of the large d a l m a n i t i d trilobites Pha-
National Park area in M a i n e ( f r o m w h e n c e the t e r m Acadian),
langocephalus dentatus
were f o r m e d in the D e v o n i a n . S e d i m e n t s of basins associated
found
within
this
unit.
with the m a g m a t i c arc in New England were heavily folded, Acadian O r o g e n y
thrusted, and m e t a m o r p h o s e d at high grade.
T h e m a j o r Wallbridge U n c o n f o r m i t y truncates the Helder-
T h e Acadian fold and thrust belt propagated from east to west,
berg strata westward from the Hudson Valley and separates t h e m
owing to the collisional c o m p r e s s i o n , reaching as far west as the
DEVONIAN
101
PERIOD
Hudson Valley region of eastern New York. T h e H u d s o n Valley
glass-making sand because of the purity of its quartz content.
fold and thrust belt is evident along the thruway between Albany
In these areas, the unit frequently exceeds 30 m in thickness and
and Kingston, Ulster County. Farther west, a foreland basin devel-
may hold up ridges in the Valley and Ridge sector of the Appala-
oped and then migrated westward in response to episodes of
chians because of its resistance to erosion. T h e Oriskany itself
thrust loading back to the east.
generally lacks trilobites b u t c o n t a i n s large robust shelled b r a -
As noted, the Acadian O r o g e n y involved a series of pulses or
c h i o p o d s , such as Costispirifer arenosus, the large circular orthid
tectophases; each shows a similar pattern: ( 1 ) quartz sandstone
Hipparionyx, and the terabratulid Rensselaeria. A thin remnant of
and limestone to (2) dark shales to gray m u d s t o n e s and (3) sand-
the O r i s k a n y S a n d s t o n e near Cayuga Lake also has yielded a b u n -
stones including red beds. T h e s a n d s t o n e - l i m e s t o n e succession
dant s p e c i m e n s of favositid corals and s o m e large Naticonema
reflects tectonic quiescence. T h e sudden switch to black shale
gastropods but few, if any, trilobites. To the southeast, in the
(flysch) records an abrupt pulsed subsidence in the foreland
Hudson Valley region, the O r i s k a n y grades into a sandy to silty
basin, and the sandstone and red beds ( m o l a s s e ) represent the
limestone referred
filling of the basin with clastic sediments.
to as the Glenerie Limestone.
In contrast to the Oriskany, the G l e n e r i e was deposited in
Tectophase I of Early Devonian age is seen primarily in
e n v i r o n m e n t s similar perhaps to those of the Kalkberg or Alsen
the n o r t h . T h e Tristates G r o u p shows an upward c h a n g e f r o m
F o r m a t i o n that were extremely favorable to a diversity of species;
orthoquartizes and limestone ( O r i s k a n y - G l e n e r i e ) through black
the unit even displays c h e r t beds similar to those in the latter
shales with K-bentonites (Esopus S h a l e ) , shallowing upward to
units. Evidence for s t o r m waves is a b u n d a n t in the Glenerie in
siltstones and sandstones and then a shift to c a r b o n a t e - s h a l e
the form of a b u n d a n t s t o r m hash layers or c o q u i n a s of shells and
(Upper Esopus S h a l e - S c h o h a r i e F o r m a t i o n ) .
fragments of trilobites. T h e Glenerie is highly fossiliferous, c o n taining an a b u n d a n t , diverse fauna of b r a c h i o p o d s , snails, and trilobites. Again, large d a l m a n i t i d trilobites appear to be a m o n g
Tristates G r o u p T h e Oriskany Sandstone appears to represent nearshore sand
the m o r e c o m m o n e l e m e n t s within this unit.
that was reworked from older sandstones and redeposited during
It s h o u l d be n o t e d that the trilobite fauna, although a n a l o -
a m a j o r rise in sea level that followed a p o s t - H e l d e r b e r g regres-
gous in s o m e ways to that f o u n d in the Kalkberg and Alsen, is
sion of seas. Erosion that preceded the Oriskany beveled the
quite distinct at a generic level from Helderberg faunas. A m a j o r
Helderberg units successively to the west, such that m o v i n g west-
faunal event separates the Helderberg faunas f r o m those of
ward from the vicinity of Catskill, G r e e n e C o u n t y , the Post Ewen,
the overlying Oriskany. T h i s faunal event very likely is associated
Alsen, Becraft, New Scotland, Kalkberg, and finally the C o e y m a n s
with the m a j o r sea-level d r o p that created the m a j o r post-Helder-
and Manlius f o r m a t i o n s underlie the Wallbridge U n c o n f o r m i t y
berg erosion surface or s e q u e n c e b o u n d a r y that underlies the
and are overlain by Oriskany S a n d s t o n e . T h e sands probably
Oriskany and Glenerie F o r m a t i o n s . Glenerie trilobites include the
accumulated in a very shallow, high-energy beach and offshore
following:
sandbar type of e n v i r o n m e n t . This e n v i r o n m e n t was conducive to the growth of abundant large b r a c h i o p o d s and even s o m e
Cordania
corals but does not appear to have been favorable to trilobites.
Homalonotus
During Oriskany t i m e , waves m u s t have broken
Paciphacops
near shore
and produced pile-ups of clean, rather well-rounded quartz sand
Synphoria
that ultimately were c e m e n t e d to f o r m the Oriskany S a n d s t o n e .
Synphoria
T h e " X Y Z " ( l o w - t o - h i g h - t o - l o w - e n e r g y ) pattern typical o f the
becraftensis major clarkei sopita stemmata
Dalmanites
bisigmatus
Odontochile
phacoptyx
Phacopina?
correlator
Synphoria
stemmata
Trimerus
vanuxemi
compacta
stemmata
Helderberg G r o u p appears to have been broken down at this time, such that no low-energy, nearshore tidal-flat deposits are
T h e Glenerie and O r i s k a n y are abruptly overlain by a dark
known. Offshore the sandbars appear to have graded into subti-
shale and m u d s t o n e unit up to 100 m thick in p o r t i o n s of the
dal, below-wave-base a c c u m u l a t i o n s of finer-grained sandy/silty
H u d s o n Valley and in the S k u n n e m u n k Outlier. T h i s unit, the
muds and lime muds that form the Glenerie L i m e s t o n e .
Esopus Shale, represents a m a j o r influx of siliciclastic muds
T h e Oriskany forms the base of the Tristates G r o u p and in
and silts that followed the rather clean sands and limestones of
New York State is a generally thin, clean quartz sandstone, rarely
the Oriskany and G l e n e r i e t i m e s . T h e o c c u r r e n c e o f thin but
exceeding 2 m in thickness. In m a n y areas of central New York,
widespread b e n t o n i t e beds in the base of the unit suggests that
the only remnant of the Tristates G r o u p consists of thin stringers
the Esopus is associated with a pulse of t e c t o n i s m that has been
of Oriskany quartz sand, s o m e of which extend downward as
referred to as the first m a j o r tectophase of the Acadian Orogeny.
m u c h as 50 cm as pipes or cavity fillings into the underlying eroded carbonates.
The
Esopus, for all
its
thickness
in
the
Hudson Valley
( > 1 0 0 m ) , appears to thin abruptly westward to a feather edge
T h e Oriskany Sandstone thickens t r e m e n d o u s l y in southern
west of C h e r r y Valley. It is apparent that a deep but rather local-
Pennsylvania and M a r y l a n d , where it c o m m o n l y is m i n e d as a
ized basin in the eastern New York and eastern Pennsylvania
102
THE
PALEOZOIC
GEOLOGY
OF
NEW
YORK
regions served as a sediment trap for the fine-grained m u d s and
m o r e calcareous and s o m e t i m e s c o n t a i n fairly abundant fossils.
silts that were being deposited o f f eroding m o u n t a i n s to the
However, the fossiliferous nature of the Schoharie is masked in
southeast or east. T h i s basin was created by the crustal b e n d i n g
m a n y o u t c r o p s by p r o m i n e n t slaty cleavage that was probably
forces produced in turn by the loading of thrust sheets as a result
developed during the later phases of the Acadian (Devonian)
o f m o u n t a i n - b u i l d i n g activity.
m o u n t a i n - b u i l d i n g episodes. Cleavage crosscuts bedding, m a k -
T h e Esopus F o r m a t i o n represents deep-water dysoxic envi-
ing collecting from the unit very difficult.
r o n m e n t s . At times the b o t t o m b e c a m e sufficiently well oxy-
A curious feature of the S c h o h a r i e is its absence in the central
genated that it was inhabited by a great a b u n d a n c e of w o r m l i k e
p o r t i o n of New York and the presence of deposits of this latest
animals
Zoophycos.
Early Devonian age b o t h east and west of the region centered on
Portions of the Esopus F o r m a t i o n are so very heavily c h u r n e d by
that
produced
the
distinctive
trace
fossil
Cayuga Lake. Recent work suggested that this may have been the
this swirly trace that in the early days of New York geology, the
result of arching of the seafloor that took place during late Early
unit was s o m e t i m e s referred to as the Cauda-galli or "roostertaiF'
D e v o n i a n t i m e , perhaps in response to the thrust loading that
grits. Relatively low oxygen, high turbidity, and possible sediment
o c c u r r e d in the Tristates tectophase of the Acadian Orogeny
trace-making/sediment-feeding
(Ver Straeten and Brett 2 0 0 0 ) . In areas west of Syracuse, the entire
worms apparently m a d e the Esopus a fairly inhospitable envi-
instability
produced
by
these
Tristates G r o u p , except for scattered thin stringers of Oriskany
r o n m e n t for m o s t shelly o r g a n i s m s . As s u c h , the unit is only very
S a n d s t o n e , has been removed at the Wallbridge Unconformity.
sparsely fossiliferous. A few layers do c o n t a i n assemblages of
W h e r e Lower D e v o n i a n strata are absent, the O n o n d a g a F o r m a -
relatively small, probably deep-water b r a c h i o p o d s such as the
tion of M i d d l e D e v o n i a n age (see below) rests directly on eroded
genus
beds of the Upper Silurian. T h e relief on this u n c o n f o r m i t y then
Pacificocoelia.
Some
mollusks,
occasionally
as
pyritized
specimens, are also k n o w n f r o m the Esopus and its equivalent
may represent at least two m a j o r episodes of erosion, o n e before
Beaver D a m Shale of Pennsylvania. However, as a whole the unit
and o n e after deposition of the Tristates G r o u p . T h i s c o m p o s i t e
is very sparse a n d has yielded little insight into the ecology of the
u n c o n f o r m i t y shows local sinkhole fillings, cavities that were dis-
t i m e , particularly with regard to trilobites.
solved out of the top of the Silurian beds prior to deposition of
Esopus shales are overlain by a s o m e w h a t m o r e silty to sandy unit, the Carlisle C e n t e r S a n d s t o n e , that c o m m o n l y contains
the overlying Lower or Middle Devonian strata (Figures 4 . 3 7 B and 4 . 3 8 A ) .
s o m e large quartz granules and the green clay m i n e r a l glauconite.
T h e u p p e r m o s t p o r t i o n o f the S c h o h a r i e , particularly near
T h i s unit locally c o n t a i n s large p h o s p h a t i c c o n c r e t i o n s near its
Albany and in the S c h o h a r i e Valley region itself, has been termed
base and displays a distinctive, sharp, s e q u e n c e - b o u n d i n g u n c o n -
the
formity at the top of the Esopus. T h e Carlisle C e n t e r seems to
is particularly n o t e d for its exquisitely preserved fossils that are
Richard
Hill
Member.
This
fossiliferous
skeletal
limestone
represent a c o n t i n u a t i o n and a c c e n t u a t i o n of coarser siliciclastic
c o m m o n l y weathered out. A rich fauna of brachiopods, corals,
sediment input into the Appalachian Basin. T h e basal c o n t a c t of
c e p h a l o p o d s , and over 15 species of trilobites, primarily d a l m a n -
this sandstone unit displays a r e m a r k a b l e assemblage of trace
itids, has been reported f r o m the S c h o h a r i e beds near Albany
fossils, which is beautifully s h o w n in cuts along U.S. Rte. 20 near
( G o l d r i n g 1 9 4 3 ) . T h i s unit represents e n v i r o n m e n t s again very
C h e r r y Valley, O t s e g o C o u n t y (Miller and R e h m e r 1 9 7 9 ) . A m -
similar to the older Glenerie and New Scotland F o r m a t i o n s . T h a t
ong other traces are distinctive r i b b o n - l i k e trails referred to as
is, the unit was deposited in low-energy offshore environments
Cruziana.
marks
that were subject to m i n o r wave agitation during storms but were
and are probably the work o f trilobites furrowing i n t o m u d s o f
well below the n o r m a l wave-base. T h i n hashes of shelly material
the underlying older and partially eroded Esopus F o r m a t i o n .
are c o m m o n in the S c h o h a r i e .
These
display V - s h a p e d
c h e v r o n - l i k e scratch
Such trilobite traces probably represent feeding activity. T h e s e
T h e S c h o h a r i e F o r m a t i o n was removed by erosion in areas
traces were produced in firm m u d s , and therefore even delicate
west of Syracuse. A thin, h e m a t i t i c , phosphate-rich sandy bed
scratch marks were preserved. However, despite these traces, there
near Syracuse m a y represent s o m e of the last vestiges of the unit
are few, if any, b o d y fossils of trilobites f o u n d in the Carlisle
in central New York. However, less silty argillaceous limestone,
C e n t e r F o r m a t i o n . To the west, the Carlisle C e n t e r b e c o m e s very
referred to as Bois Blanc Formation, is present intermittently in
t h i n , very rich in glauconite and p h o s p h a t e , and appears to over-
the area f r o m near Phelps, O n t a r i o C o u n t y ( n o r t h o f Seneca
step the thin Esopus shale. In the H u d s o n Valley region, the unit
L a k e ) , westward to Buffalo and into C a n a d a . T h e Bois Blanc
is overlain and grades laterally into the highest f o r m a t i o n of the
b e c o m e s a p r o m i n e n t unit in O n t a r i o and westward into the
Tristates G r o u p , the S c h o h a r i e
F o r m a t i o n , previously called
" S c h o h a r i e Grit."
M i c h i g a n Basin. T h i s unit is rich in b r a c h i o p o d s and corals that have species identical to those f o u n d in the S c h o h a r i e of eastern
T h e S c h o h a r i e F o r m a t i o n is dated as close to the e n d of
New
York.
A
few
the Early Devonian (the E m s i a n S t a g e ) . S c h o h a r i e beds range
anchiops,
also been o b t a i n e d from these rocks.
relatively
regular
cyclic
alternation
between
more
and
less
minuscula,
Burtonops
f r o m a b o u t 10 to over 3 0 c m (1 f o o t ) in thickness and display a c a r b o n a t e - r i c h , silty to sandy m u d s t o n e . C r e a m - c o l o r e d beds are
Maurotarion
trilobites, and
cristatus,
Crassiproetus
Anchiopella
species,
have
T h e c o m p l e t e S c h o h a r i e - B o i s Blanc trilobite listing is as follows:
FIGURE 4.37. New York d u r i n g the early M i d d l e D e v o n i a n . A. During d e p o s i t i o n of the O n o n d a g a Limestone. B. Lower a n d Middle Devonian stratigraphic chart for the Northeast. From C a s s a a n d Kissling (1982), N e w York State G e o l o g i c a l Association. R e p r o d u c e d with permission.
FIGURE 4 . 3 8 . U p p e r S i l u r i a n / O n o n d a g a Limestone. A. Silurian-Devonian Wallbridge Unconformity (arrow). Darker gray d o l o s t o n e (Akron Formation (a), U p p e r Silurian) at the b a s e of the picture is overlain along an irregular u n c o n formity by light gray O n o n d a g a Limestone (b) ( M i d d l e Devonian). O a k s Corners Quarry, O a k s Corners, Ontario County. B. M i d d l e D e v o n i a n O n o n d a g a Limestone, N e d r o w Member. Note the cyclic b a n d i n g of dark chert-rich limestone a n d lighter gray fossiliferous, n o n c h e r t y limestone. Quarry off Rte. 5, Leroy, G e n e s e e County.
DEVONIAN Anchiopella
105
PERIOD anchiops
Burtoiwps
Anchiopella
cristatus
anchiops
Calymene
Coniproetus
angustifrons
Coniproetus
Corycephalus
regalis
Crassiproetus
Echinolichas
hispidus
Maurotarion Phacops? Schoharia
Synphoria?
grandis
in the Acadian m o u n t a i n terrain and in the Appalachian foreland
calliccra
basin.
arenicolus
Pseudodechenella
emarginata
Terataspis
O n o n d a g a ash beds are a harbinger of renewed tectonic activity
schohariensis
Mystrocephala
clarksoni
this ash recently have been dated using u r a n i u m - l e a d dating, to yield a very precise date of 3 9 0 ± 0.5 million years ago. T h e
conradi
Kettneraspis
minuscula
sobrinus
platys
T h e base of the M i d d l e D e v o n i a n O n o n d a g a F o r m a t i o n is
hesionea
m a r k e d by a locally sandy, pinkish gray crinoidal limestone unit
concinnus
Trypaulites
in m a n y areas, a p o r t i o n of the Edgecliff M e m b e r . T h e Edgecliff
erinus
c o n t a i n s s o m e of the largest c r i n o i d c o l u m n a l s k n o w n in any unit in the Paleozoic. Trilobites, as well as diverse corals, are abundant and
Middle Devonian
represented
Crassiproetus
by
Viaphacops
bombifrons,
Calymene platys,
and
crassimarginatus.
Tectophase II of the Acadian O r o g e n y o c c u r r e d d u r i n g M i d -
T h e depositional e n v i r o n m e n t of the grainstone facies is
dle Devonian. A basal m i n o r sandstone and thick limestone
thought to represent offshore ( Y - z o n e ) shallow-water shoal envi-
(Onondaga
r o n m e n t s , similar to older units such as the Lower Devonian
Group)
were
deposited
in
quiescent
conditions
(Figure 4 . 3 7 A ) . A sudden shift to black shale (Marcellus F o r m a -
Becraft,
t i o n ) , then shallowing upward through siltstones and sandstones
L o c k p o r t G r o u p . However, in places, where the water was s o m e -
into red beds, records first tectonic deepening and then filling of
what deeper, at least the upper Edgecliff is c o m p o s e d of relatively
the foreland basin.
thick micritic or fine-grained l i m e s t o n e with extremely a b u n d a n t
Coeymans,
and
portions
o f the
still-older
Silurian
bluish gray to chalky white c h e r t . T h e source of this siliceous Onondaga Limestone
material is p o o r l y k n o w n . However, the c h e r t - r i c h beds may have
T h e Middle Devonian (Eifelian Stage) b o u n d a r y o c c u r s at
been derived from finely particulate organic silica, such as sponge
or near the base of the O n o n d a g a F o r m a t i o n in New York State
spicules, that m u s t have developed in e n o r m o u s quantity in the
and its equivalents in Pennsylvania. T h e O n o n d a g a is an e x -
s o m e w h a t quieter water areas of the Edgecliff deposition. Chert
tremely widespread unit that correlates with other limestones in
is not c o m m o n in the high-energy shoal facies, perhaps because
the Midwest, such as the Jeffersonville L i m e s t o n e of Indiana and
the fine-grained silica required for its f o r m a t i o n was w i n n o w e d
Kentucky and the C o l u m b u s
L i m e s t o n e o f O h i o . T h e early
Middle Devonian appears to have been a t i m e of very widespread,
from these areas and removed to the slightly deeper regions of the basin.
rather u n i f o r m topography. T h i s initial transgression of M i d d l e
Fossils are generally sparse in the O n o n d a g a cherty facies but
Devonian seas o c c u r r e d during a t i m e of t e c t o n i c quiescence.
include m o d e r a t e l y a b u n d a n t f r a g m e n t s and articulated speci-
Hence, there was little tendency for the d e v e l o p m e n t of deep
mens
of trilobites.
basins or m a j o r archlike swells at this t i m e . T h e O n o n d a g a there-
ifrons,
Kettneraspis
fore spread as a sheetlike unit that was deposited at relatively
slab
uniform depths of a few tens of meters over a vast tract of eastern
from the c h e r t y facies d u r i n g the c o n s t r u c t i o n o f the H u m b o l t
North America. T h e unit does grade laterally into shallow-water
Parkway in Buffalo.
of
The
trilobites
callicera,
articulated
and
found
are
Odontocephalus
Odontocephalus
humboltensis
Viaphacops bombaegeria. was
A
large
excavated
sands in regions of southern Pennsylvania and the southern
T h e Edgecliff M e m b e r also is n o t e d for the o c c u r r e n c e of
Appalachians. However, from the H u d s o n Valley to Buffalo, the
small to m e d i u m - s c a l e b i o h e r m s or reefs. In areas of eastern
O n o n d a g a displays considerable uniformity, varying primarily
New York
only in the relative a b u n d a n c e of c h e r t and skeletal-rich beds
New York, near Buffalo and A m h e r s t , Erie C o u n t y , these b i o -
(Figure 4 . 3 8 B ) .
h e r m s were developed as low m o u n d s , up to perhaps 1 km in
T h e basal Edgecliff M e m b e r is a coral-rich crinoidal grain-
near
Albany
and
Syracuse,
and
in
westernmost
diameter and generally a few meters to a b o u t 10 m in height.
stone that passes upward laterally into very c h e r t - r i c h , fine-
B i o h e r m s were c o m p o s e d
grained limestone. Shaly beds of the Nedrow M e m b e r probably
corals. T h i c k e t s of colonial rugose corals near their bases pass
primarily o f rugose and
tabulate
record m a x i m u m transgression. Upper p o r t i o n s o f the M o o r e -
upward to l i m e - m u d s t o n e m o u n d s with a b u n d a n t favositid and
house and the overlying Seneca M e m b e r b e c o m e increasingly
s o m e o t h e r colonial and solitary rugose corals. Trilobites and
cherty and micritic in c o m p o s i t i o n . T h e y also contain s o m e of
even b r a c h i o p o d s are scarce in these facies, which seem to have
the most widespread bentonite beds k n o w n in the Appalachian
been fully d o m i n a t e d by corals a n d crinoids. T h e source of the
Basin. Particularly notable in this cluster, which is s o m e t i m e s
l i m e m u d is a mystery, but it may represent algal deposition.
termed
to
However, shaly beds o n the margins o f s o m e o f the b i o h e r m s
as Onondaga Indian Nations Ash (Figure 4 . 3 9 A ) . T h i s unit is
evidently represent a type of protected quieter water environ-
locally up to 30 cm (1 foot) thick and contains a m i x t u r e of shale
m e n t , perhaps in the lee of the b i o h e r m s . W h i l e trilobites are
and actual volcanic ash beds. Extracted zircon crystals f r o m
not c o m m o n in the reef f r a m e w o r k of the Edgecliff b i o h e r m s ,
the
Tioga
Bentonite
cluster,
is
the
ash
referred
FIGURE 4.39. M i d d l e D e v o n i a n rocks. A. S h a r p c o n t a c t b e t w e e n the light gray O n o n d a g a Limestone (a) ( M i d d l e Devonian) a n d black B a k o v e n (Union Springs) Shale (b) of basal Hamilton G r o u p . Partings with plants mark the positions of bentonites (arrows). Kaaterskill Creek, b e l o w Rte. 23A, Catskill, Greene County. B. M i d d l e Devonian Mount Marion Formation s h o w s c o a r s e n i n g a n d t h i c k e n i n g u p w a r d from lower shaly b e d s to u p p e r s a n d s t o n e s . H i g h Falls, Kaaterskill Creek, near Saugerties, Ulster County.
DEVONIAN
PERIOD
107
interfingering shaly beds have yielded s o m e remarkable finds,
c h a n g e , and P h a c o p i d a e and H o m a l o n o t i d a e c o n t i n u e but in
including the e n o r m o u s spiny trilobite Terataspis grandis, o n e of
s o m e w h a t modified forms.
the largest k n o w n of all Devonian trilobites. F r a g m e n t s of this
A
unusual lichid were formerly rather a b u n d a n t in the Vogelsanger
follows:
complete
listing
of
the
reported
Onondaga
trilobites
Q u a r r y at East A m h e r s t , Erie County. T. grandis has also been found in the O n o n d a g a in O n t a r i o , and fragments have been
Acanthopyge
found in central New York.
Australosutura
T h e Edgecliff M e m b e r is sharply overlain in m a n y localities by
(Lobopyge)
Calymene
contusa
gemmaea
Asaphus?
acantholeurus
Bellacartwrightia
platys
pleione
Ceratolichas
dracon
a m u c h m o r e argillaceous, fine-grained, and n o n c h e r t y limestone
Ceratolichas
and calcareous shale, referred to as the Nedrow Member. In places
Coronura
the Nedrow contains very dark gray or almost black shale beds
Coronura
representing dysoxic m u d d y - b o t t o m c o n d i t i o n s . T h e s e beds, not
Crassiproetus
brevispinosus
Crassiproetus
greenish gray shaly limestones of the Nedrow are extremely rich
Crassiproetus
neoturgitus
Crassiproetus
stummi
not only in the solitary rugose and small tabulate corals b u t also
Echinolichas
Echinolichas
hispidiis
gryps
Coniproetus
aspectans myrmecophorus
a
diversity of b r a c h i o p o d s
proetids, small
Pseudodechenella
odontopleurid,
Viaphacops
clara
Kettneraspis
and and
trilobites, Coniproetus
callicera,
and
eriopsis
the
Harpidella
stephanophora
Harpidella
folliceps,
the
Kettneraspis
callicera
Mannopyge
the
phacopid
Mystrocephala
ing and deepening o n c e again. T h e M o o r e h o u s e M e m b e r records
Odontocephalus Otarion?
bifidus
Odontocephalus
coronatus
Odontocephalus
selenurus
humboltensis sp.
hybrida
from crinoidal packstone with a b u n d a n t rugose corals, albeit
Paciphacops
with no development of reefs, to shaly and c h e r t - r i c h limestone
Proetus
that contains very a b u n d a n t b r a c h i o p o d s and trilobites. T h e
Proetus
trilobites
Pseudodechenella
Odontocephalus selenurus as well
as
the
Otarion?
diadema minuscula
logani
Proetus
microgemma
Proetus
ovifrons
Proetus
tumidus
stenopyge canaliculata
delphinulus
Pseudodechenella
Synphoria
concinnus
Terataspis
o f the shaly beds o f the M o o r e h o u s e .
Trypaulites
erinus
Trypaulites
Viaphacops
aegeria
Otarion?
large synphoriid Coronura aspectans o c c u r in a b u n d a n c e in s o m e T h e f i n e - g r a i n e d limestone beds o f the upper M o o r e h o u s e
halli
Odontocephalus
Odontocephalus
conditions rather similar to p o r t i o n s of the Edgecliff. It varies
sp.
varicella
Odontocephalus
T h e upper two m e m b e r s of the O n o n d a g a record a shallow-
pygmaeus
crassimarginatus
including
bombifrons.
Viaphacops and
Helena
Corycephalus
surprisingly, are very sparse in fossils. However, s o m e of the
in
folliceps
Coronura
bombifrons
clara
grandis
Viaphacops
macrops pipa
and Seneca (and their equivalent in the Selinsgrove F o r m a t i o n of Pennsylvania) tend to be sparsely fossiliferous, but certain
Certain beds near the top of the Seneca M e m b e r are distinctive
bedding planes do c o n t a i n small b r a c h i o p o d s and, most notably,
in c o n t a i n i n g an a b u n d a n c e of fossil fish remains. In the area
an a b u n d a n c e of O. selenurus trilobites. T h i s synphoriid appears
between Syracuse and the H u d s o n Valley, the erosional top of
to have been a m o n g the m o s t tolerant of o r g a n i s m s of the low-
the O n o n d a g a L i m e s t o n e is m a r k e d by a very distinct b o n e bed
oxygen, l i m e - m u d sea b o t t o m . T h e facies o f the upper O n o n d a g a
with a b u n d a n t fish teeth ( k n o w n as Onychodus) and bones. T h e s e
resembles dalmanitid-rich p o r t i o n s of the Helderberg, such as
b o n e beds probably a c c u m u l a t e d during a period of very slow
the New Scotland and Port Ewen, and even the sparsely fossilif-
s e d i m e n t a t i o n on the seafloor. T h e y are abruptly overlain by the
erous calcareous m u d s t o n e s of the Rochester F o r m a t i o n in the
sooty black shales
of the
Union
Springs
F o r m a t i o n , which
Silurian. T h e s e facies t h r o u g h o u t the Silurian to M i d d l e D e v o n -
ushered in a new tectophase with abrupt deepening of the basin
ian time appear to have h a r b o r e d an a b u n d a n c e of dalmanitid
and input of a large a m o u n t of dark siliciclastic m u d that
trilobites.
evidently was being i m p o r t e d from uprising m o u n t a i n s of the
T h e highest beds of the O n o n d a g a in New York, b e l o n g i n g to the Seneca M e m b e r , overlie a very widespread ash b e d , the
second Acadian tectophase (Figure 4 . 2 1 ) . W i t h the U n i o n Springs F o r m a t i o n begins the M i d d l e Devonian H a m i l t o n G r o u p .
O n o n d a g a Indian Nations B e n t o n i t e . T h e Seneca is generally sparsely fossiliferous, dark micritic limestone in the Finger Lakes
Hamilton Group—General
area that grades to m o r e fossiliferous beds in western New York.
T h e M i d d l e Devonian H a m i l t o n G r o u p (Figure 4 . 4 0 ) is o n e
T h e Seneca typically contains b r a c h i o p o d s , small burrows (Chon-
of the m o s t richly fossiliferous of the New York Devonian. Its
drites),
and
a
few
scattered
fragments
of
Odontocephalus
trilobites.
fossil faunas have been well studied since the times of James Hall. Generally, the fossil assemblages are arranged in a series of asso-
At the close of O n o n d a g a deposition, m a n y families of trilo-
ciations, or b i o f a c i e s , that represent distinct environments from
bites disappeared from New York. Lichiids, o d o n t o p l e u r i d s , caly-
deeper-water black shales with low-diversity b r a c h i o p o d assem-
menids, dalmanitids, and synphoriids have never been reported
blages to shallow-water coral beds, and nearshore, sandy, clam-
from beds above the O n o n d a g a . However, proetids show little
d o m i n a t e d assemblages.
FIGURE 4.40. New York d u r i n g the M i d d l e D e v o n i a n Hamilton depositions. A. M a p d u r i n g the m i d d l e Hamilton time. B. Cross section s h o w i n g the e r o d i n g A c a d i a n Mountains. From Isachson et al. (1991). Printed with p e r m i s s i o n from the N e w York State M u s e u m , Albany, NY C. Stratigraphic cross section of the Hamilton formation d e p o s i t s . From Linsley (1994). R e p r o d u c e d with p e r m i s s i o n .
DEVONIAN
109
PERIOD
Lower H a m i l t o n Marcellus F o r m a t i o n
stones contains a rich, diverse fauna across the state. In the
T h e lower Marcellus or U n i o n Springs beds that overlie the
H u d s o n Valley region, this unit is a coral-rich bed that has been
Seneca M e m b e r are primarily black shales. D u r i n g deposition of
referred to as the Halihan Hill bed (Griffing and Ver Straeten
these sediments, oxygen levels were very low in the deeper parts
1 9 9 1 ) . Farther westward the corals b e c o m e less c o m m o n and are
of the seafloor (late Eifelian S t a g e ) . However, d u r i n g deposition
absent a r o u n d S c h o h a r i e , New York, but a diverse fauna of b r a -
of the upper portion of the U n i o n Springs, there was evidently a
c h i o p o d s , b r y o z o a n s , bivalves, and o t h e r fossils occurs from here
change. Higher beds of the U n i o n Springs in the Hudson Valley,
westward. Trilobites are scarce, but the first representatives of the
referred to as the Stony Hollow M e m b e r , are characterized by
Eldredgeops rana lineage, k n o w n in New York, o c c u r within the
calcareous
siltstones,
which
contain
a
relatively sparse
and
Halihan Hill bed and its lateral equivalent, the LeRoy bed in the
low-diversity fauna of auloporid corals, s o m e b r a c h i o p o d s , and
western part of New York. A Harpidella sp. has also been found.
notably, the trilobite Dechenella haldemani. C o m m o n pygidia of
T h e fauna o f this h o r i z o n m a r k s the i n c u r s i o n o f m a n y o f the
this trilobite and rare cephala o c c u r in a few beds of a p o r t i o n
typical H a m i l t o n species. T h e species that o c c u r within this bed
of the Stony Hollow. T h i s trilobite has been traced widely in rocks
are f o r m s that persist t h r o u g h o u t the entire r e m a i n d e r of the
that date from the late Eifelian Age. For e x a m p l e , it is f o u n d in
H a m i l t o n G r o u p . Moreover, individual assemblages within the
a thin ( 2 0 c m ) , pale gray limestone ( t h e C h e s t n u t Street b e d )
Halihan Hill/Leroy bed recur at multiple levels of the higher
that occurs just below the C h e r r y Valley L i m e s t o n e t h r o u g h o u t
H a m i l t o n succession. T h e fauna o f this b e d shows virtually
central and western New York. Very similar proetids also are
n o t h i n g in c o m m o n with similarly shallow-water, c o r a l - and b r a -
found in a c o m p a r a b l e position in the southern and central
c h i o p o d - r i c h faunas o f the U n i o n Springs/Stony Hollow m e m -
Appalachians as far south as M a r y l a n d . A related species is f o u n d
bers. A few species are recurrent O n o n d a g a taxa that seem to have
in the latest Eifelian of the Michigan Basin region. Dechenella
c o m e back into the Appalachian Basin following a period of
haldemani is just o n e of a suite of unusual species of fossils f o u n d
outage associated with the unusual Stony Hollow incursion.
in this assemblage.
The brachiopods,
the
proetid
trilobites,
In the Hudson Valley area, the Hallihan Hill bed is overlain by
crinoids, and other invertebrate fossils display few similarities
a thick (up to 5 0 0 m ) succession of silty shales, siltstones, and
with the older O n o n d a g a fauna and even fewer with those of the
sandstones o f the M o u n t M a r i o n F o r m a t i o n . T h e M o u n t M a r i o n
overlying Hamilton beds. T h e Stony Hollow fauna seems to rep-
F o r m a t i o n displays a series of small-scale cycles, a few tens of
resent the brief incursion of an assemblage of o r g a n i s m s that n o r -
meters in thickness, s u p e r i m p o s e d on a generally c o a r s e n i n g - and
mally lived in w a r m e r tropical areas to the northwest, represented
shallowing-upward trend. T h e gray m u d s t o n e s are sparsely fos-
in the present-day by the C a n a d i a n Arctic.
siliferous, but the caps of the small cycles are f o r m e d by shell beds unit,
with a n u m b e r of species of b r a c h i o p o d s and c l a m s . T h e trilobite
overlies the Union Springs F o r m a t i o n t h r o u g h o u t New York,
E. rana and asteropyge species have been reported from these
Pennsylvania, M a r y l a n d , and West Virginia. C h e r r y Valley is an
levels. Dipleura dekayi may o c c u r as well in s o m e of the sandy
unusually good example of a condensed bed that f o r m e d during
beds, but it is not c o m m o n .
T h e C h e r r y Valley L i m e s t o n e , a thin ( 0 . 5 to 3 . 0 m )
a period of sea-level rise. Following the shallowing Stony Hollow
Westward, the various units display a gradual transition from
conditions, there must have been a period of m i n o r seafloor
silty m u d s t o n e s into m e d i u m and dark gray shales. T h e lower
erosion, as the base of the C h e r r y Valley is typically sharp. T h e
p o r t i o n s of the M o u n t M a r i o n above the Halihan Hill bed grade
Cherry Valley itself is c o m p o s e d of the remains of small conical
into the C h i t t e n a n g o Shale M e m b e r o f the Marcellus F o r m a t i o n
pelagic organisms, referred to as styliolinids, and with c e p h a -
in central New York. T h i s black, rusty shale with c o n c r e t i o n s
lopods, for which it is particularly noted. S o m e of the earliest
c o n t a i n s very few fossils o t h e r than
abundant goniatitic a m m o n o i d s (Agoniatites vanuxemi) o c c u r
c e p h a l o p o d s , and styliolinid remains. However, it passes upward
scraps of w o o d , s o m e
within the C h e r r y Valley L i m e s t o n e . However, no trilobites are
into m e d i u m gray shales of the Bridgewater M e m b e r and the
known from the C h e r r y Valley proper.
overlying Solsville S a n d s t o n e and Pecksport Shale. T h e s e units
T h e C h e r r y Valley M e m b e r is overlain abruptly by O a t k a Creek
are noted for the o c c u r r e n c e of exceptionally well-preserved bra-
(Chittenago) black shale that resembles the underlying U n i o n
c h i o p o d and molluscan remains. A very few s p e c i m e n s of the
Springs F o r m a t i o n . Most of this unit represents deep-water a c c u -
trilobite E. rana showing primitive patterns in terms of eye struc-
mulation of anoxic muds. However, there are hints of a p r o f o u n d
ture ( 1 8 vertical files of lenses) have been recorded in these beds
faunal change within these rocks. Fossils are rare in the O a t k a
f r o m the region of the H a m i l t o n - t y p e area in the C h e n a n g o
Creek black shales. But a few gray layers c o n t a i n f o r m s typical of
Valley (Eldredge 1 9 7 2 ) . To the west only the upper two-thirds to
the higher Hamilton G r o u p and not the underlying U n i o n Springs
o n e - f o u r t h o f the O a t k a C r e e k (Marcellus) F o r m a t i o n represent
or O n o n d a g a . Most notable is a fossiliferous bed that occurs vari-
m e d i u m gray m u d s t o n e s ( C a r d i f f F o r m a t i o n ) ; these are typically
ably from just a few centimeters in western New York up to about
only very sparsely fossiliferous.
50 m ( 1 6 0 feet) in the east, above the C h e r r y Valley L i m e s t o n e .
T h e thick M o u n t M a r i o n F o r m a t i o n (Figure 4 . 3 9 B ) represents
This thin bed ( 1 0 to 5 0 c m ) of m e d i u m gray shale and thin lime-
m u d s , silts, and sands shed from Acadian uplifts into a rapidly
THE
110
PALEOZOIC
GEOLOGY
OF
NEW
YORK
subsiding foreland basin. T h i s succession thins abruptly westward
only sparsely fossiliferous. T h e Delphi Station and Pompey are
from m o r e than 5 0 0 m to less than 20 m in western New York,
relatively rich in small b r a c h i o p o d s and trilobites.
where thin m u d s of the O a t k a Creek Shale a c c u m u l a t e d deep
As with the Marcellus shales, the Skaneateles Formation tends
anoxic waters. Rapid a c c u m u l a t i o n o f sediments eventually o u t -
to pass westward into poorly differentiated, dark gray to black
stripped subsidence near the Hudson Valley, where the M o u n t
shales that generally contain tew f o s s i l s but are characterized in
M a r i o n shallows upward from deep basinal c o n d i t i o n s to shallow
m a n y areas by leiorhynchid b r a c h i o p o d fauna or small bivalves.
sandy shelf. T h e upper beds of the M o u n t M a r i o n F o r m a t i o n are
T h e s e deeper-water facies of the Levanna Shale yield relatively
sandstones with s o m e c o n g l o m e r a t e s . T h e latter contain quartz
a b u n d a n t E. rana and s o m e asteropyge specimens, but D. dekayi
and chert pebbles, s o m e of which m a y be reworked from older
is very rare. S o m e w h a t m o r e diversified b r a c h i o p o d s , auloporid
Devonian units uplifted during the Acadian Orogeny. T h e s e pass,
coral, and trilobite assemblages are found at levels that seem to
in turn, upward into gray flaggy siltstone and sandstone beds,
c o r r e s p o n d with the caps of the Delphi Station and Pompey
assigned to the Ashokan F o r m a t i o n , c o n t a i n i n g primarily plant
Members.
material and a few horizons of low-diversity b r a c h i o p o d a s s e m blages. T h e s e beds are interpreted as tidal-flat sands to n o n m a rine beds. T h e y are overlain gradationally by m a r o o n or red strata
Ludlowville F o r m a t i o n The
Centerfield
Member
at
the
base
of
the
overlying
o f the Plattekill and Manorkill F o r m a t i o n s . T h e s e n o n m a r i n e ,
Ludlowville F o r m a t i o n displays an abrupt shallowing trend. In
meandering river deposits typically show channeled sandstones
western New York, the Centerfield M e m b e r is a classic example
that fine upward through a few meters into red m u d s t o n e s c o n -
of a shallowing to deepening shale to c a r b o n a t e to shale cycle
taining p l a n t - r o o t marks and m u d cracks. Such evidence indi-
within the H a m i l t o n G r o u p . A thin basal succession of gray shales
cates that the relatively deep basins that o c c u p i e d the Hudson
passes upward into m u d s t o n e s and finally skeletal limestones. A
Valley region during Middle Devonian times were completely
nearly s y m m e t r i c a l transition back through calcareous m u d -
infilled with terrigenous detritus derived from the second tec-
stones to m e d i u m or dark gray shales of the Ledyard M e m b e r
tophase o f the Acadian O r o g e n y (Figure 4 . 3 4 ) .
o c c u r s in the upper half of the Centerfield. In places, a phosphatic pebble bed marks the t o p of the unit. The calcareous mudstone facies of the Centerfield pass eastward in central New York into
Skaneateles F o r m a t i o n In central to western New York, the Pecksport or C a r d i f f Shale
calcareous siltstones and cross-bedded sandstones, marking out
(upper Marcellus) is gradationally to sharply overlain by the
a m a j o r shallowing-up cycle that c o m m e n c e s with dark gray
second m a j o r H a m i l t o n l i m e s t o n e or calcareous siltstone, that is,
shales.
the Stafford and Mottville M e m b e r s at the base of the Skaneate-
A c o m p l e t e s p e c t r u m of H a m i l t o n biofacies is observable
les F o r m a t i o n . At this level a diverse H a m i l t o n fauna reappears
within the Centerfield and adjacent units. It overlies and under-
for the first t i m e above the Halihan Hill coral bed, and it displays
lies dark gray shales with leiorhynchid b r a c h i o p o d fauna that
m i n o r m o d i f i c a t i o n s , m o s t notably the loss of a few O n o n d a g a
probably represent deep offshore m u d s , well below the storm
holdover species and a greatly increased a b u n d a n c e of trilobites.
wave-base. T h e s e shales are transitional into gray shales charac-
Both Eldredgeops species and various f o r m s of astropygids, Ken-
terized by a a m b o c o e l i i d b r a c h i o p o d - r i c h fauna and very a b u n -
nacrypheus harrisae and a Greenops species (assigned
dant
in
the past
to G. boothi), are c o m m o n for the first t i m e in the Mottville beds
trilobites,
Harpidella
such
craspedota,
as
Bellacartwrightia jennyi,
Monodechenella
Eldredgeops
macrocephala,
and
rana, Mys-
of central New York. Joining t h e m is the h o m a l o n o t i d trilobite D.
trocephala baccata, and finally into the highly diversified coral and
dekayi. T h i s species o c c u r s in considerable a b u n d a n c e in s o m e of
b r a c h i o p o d assemblages that typify the calcareous mudstones
the silty beds of the Mottville, and especially in a siltstone capping
and limestones of the middle Centerfield. T h e s e beds are par-
a small cycle approximately 10.5 to 1 2 . 0 m above the top of the
ticularly noted in western
Mottville M e m b e r . T h i s latter unit, the C o l e Hill t o n g u e of the
abundant
Delphi Station Shale, is widely k n o w n as a source of these large
c o n c r e t i o n a r y limestone a b o u t 3 0 c m (1 foot) below the coral-
trilobites, particularly in
rich limestones of the middle Centerfield contains unusually
the
vicinity of Sangerfield, O n e i d a
proetid
New York as a source of rather
trilobites.
Pseudodechenella
In
rowi
particular, o n e thin
in
contorted
(10cm)
County, where large n u m b e r s of s p e c i m e n s have been o b t a i n e d
preserved
in beds rich in large bivalves and certain b r a c h i o p o d species.
which suggests these o r g a n i s m s were caught up in an unusually
orientations,
the
rapid s t o r m burial event. T h i s bed has been traced for over 80 km
Skaneateles c o r r e s p o n d t o three m e m b e r s o f central New York:
f r o m the Buffalo region westward to the type section at Center-
the
f i e l d , O n t a r i o County, near Canandaigua Lake. T h e C h e n a n g o
Three
higher,
Delphi
Station
major
shallowing-upward
(40m),
Pompey
(25m),
cycles and
in
Butternut
M e m b e r s (up t o 6 0 m ) . T h e top o f the P o m p e y c o n t a i n s l i m e -
M e m b e r siltstone and sandstones facies also display Dipleura
stone c o n c r e t i o n s that have been traced f r o m western New York
dekayi,
eastward into the C h e n a n g o Valley region. T h e upper Butternut
Formation.
as
do
similar
facies
in
the
underlying
Skaneateles
M e m b e r is typically the darkest shale of the Skaneateles F o r m a -
T h e bulk of the higher Ludlowville F o r m a t i o n is c o m p o s e d of
tion t h r o u g h o u t m o s t of western and central New York and is
black and dark to m e d i u m gray shales and mudstones of the
DEVONIAN
PERIOD
111
Ledyard and Wanakah M e m b e r s in western New York and their
to those seen in the older Centerfield M e m b e r . Again, well over 100
equivalents in central New York, the silty m u d s t o n e s of the O t i s c o
species of b r a c h i o p o d s , b r y o z o a n s , crinoids, mollusks, and trilo-
Shale and the siltstone of the overlying Ivy Point M e m b e r .
bites, including relatively large astropyges, Bellacartwrightia and
T h e Ledyard Shale in western New York is m e d i u m to dark
Greenops, species, and additionally E.
rana and M.
macrocephala
gray shale and m u d s t o n e . It is particularly noted for an o c c u r -
have been o b t a i n e d f r o m the Jaycox beds. T h e y also represent the
rence of an interval about 6 m ( 2 0 feet) above the Centerfield that
first
appearance
of the
trilobite Australosutura gemmaea.
is very rich in small spheroidal nodules of pyrite. T h e s e beds, termed the Alden Pyrite Beds, yield a moderately diverse fauna
Moscow Formation
dominated by b r a c h i o p o d s but also c o n t a i n i n g very a b u n d a n t remains of trilobites E.
rana and
Greenops grabaui,
T h e highest f o r m a t i o n of the H a m i l t o n G r o u p , the Moscow, is
typically as
b o u n d e d at its base by an unusually widespread skeletal limestone
enrolled individuals and often as the nuclei of pyrite c o n c r e t i o n s .
c o m p o s e d primarily o f ossicles o f crinoids and s o m e fragmentary
Babcock and Speyer ( 1 9 8 7 ) reasoned that these enrolled trilobite
or c o m p l e t e colonies of favositid and rugosan corals. T h i s unit,
beds reflect unusual c o n d i t i o n s on the seafloor under which
the T i c h e n o r M e m b e r , has been traced from Lake Erie eastward
storm disturbance stirred up hydrogen s u l f i d e - r i c h m u d s . Trilo-
to the S c h o h a r i e Valley region. It appears to represent a trans-
bites responded to the toxicity of the waters and perhaps their
gressive lag deposit f o r m e d in shallow, relatively sediment-starved
turbidity with the typical escape reaction of e n r o l l m e n t b u t were
waters. It overlies an erosional d i s c o n f o r m i t y f o r m e d during a
later buried by clouds of m u d suspended during the s a m e s t o r m
m a j o r regression at which beds of the Jaycox and subjacent units
event. T h e Alden beds c a n n o t be traced into the Finger Lakes,
o f the Ludlowville were locally t r u n c a t e d . S o m e o f the T i c h e n o r
where the Ledyard Shale is predominately fissile or platy black
L i m e s t o n e may actually be c o m p o s e d of fossils reworked from the
shale and represents low-oxygen e n v i r o n m e n t s . Trilobites, h o w -
older Ludlowville units. T h e T i c h e n o r passes upward into cal-
ever, are again c o m m o n in the gray silty m u d s t o n e facies of the
careous, sparsely fossiliferous m u d s t o n e of the Deep Run M e m b e r
equivalent Otisco M e m b e r that replaced the typical Ledyard
that is the o n l y o c c u r r e n c e of the trilobite Cyphaspis. T h e Deep
facies east of O w a s c o Lake. T h e O t i s c o is also n o t e d for the o c c u r -
R u n is overlain by a thin ( 3 0 to 5 0 c m ) silty M e n t e t h Limestone,
rence of two coral-rich s u b m e m b e r s , the Staghorn Point and the
which is m o s t n o t e d as a source of silicified fossils ( B e e c h e r 1893a)
Joshua coral beds. T h e s e are f o r m e d of thickets or b i o s t r o m e s of
that includes very early growth stages of m a n y species, such as
solitary rugose corals with s o m e tabulates. O t h e r fossils tend to
protaspides o f trilobites. T h e lowest part o f the M o s c o w F o r m a -
be rare within the coral thickets, but on the periphery of the
tion ( T i c h e n o r , D e e p R u n , M e n t e t h ) is also n o t e d as the source of
Joshua b i o s t r o m e , clusters of E. rana have been collected.
s o m e o f the largest s p e c i m e n s o f trilobites. T h e largest k n o w n
T h e Wanakah M e m b e r gray shales are exceptionally rich in
E.
rana,
Bellacartwrightia
phyllocaudata,
and
M.
macrocephala
are
fossils, at certain levels, including corals, b r a c h i o p o d s , bryozoans,
o b t a i n e d from the D e e p R u n , but similarly large individuals are
crinoids, trilobites, and others. Over 2 0 0 fossil species have
f o u n d in the M e n t e t h L i m e s t o n e and K a s h o n g Shale. T h e s e
been reported from the W a n a k a h Shale in western New York.
muddy-bottomed,
A m o n g these are about six or seven species of trilobites. T h e s e
favorable to the growth of these trilobites. However, an enigma
shallow-water
environments
were
highly
species are most a b u n d a n t in a series of thin argillaceous l i m e -
associated with these beds is the relative paucity of small individ-
stones that o c c u r low in the W a n a k a h from Lake Erie at least
uals. Because trilobites m o l t , o n e should see a record of these
to Canandaigua Lake. T h e s e are the famed "trilobite b e d s " of
various growth
Amadeus Grabau ( 1 8 9 8 - 1 8 9 9 ) . Along with large n u m b e r s o f
absence of these early stages may suggest that trilobites were rather
E.
G.
m o r e m o b i l e creatures and that the shallow-water m u d d y envi-
grabaui. Such trilobite bed facies, typically associated with small
r o n m e n t s represented by the D e e p Run and Kashong facies were
rana
are
found
P.
rowi,
Bellacartwrightia
whiteleyi,
and
stages observed as disarticulated
parts.
The
that
inhabited primarily by m a t u r e individuals. S o m e m o d e r n crus-
occupied an offshore mud b o t t o m during times of low net sedi-
taceans are k n o w n to undergo widespread m i g r a t i o n s of this sort.
solitary
(Stereolasma)
corals,
represent
a
distinctive biota
ment input. T h e s e thin limestones have m u c h in c o m m o n with
Overall, the T i c h e n o r - D e e p Run succession represents a gradual
the Browns Creek Bed of the Centerfield. Like the latter bed, they
deepening f r o m near wave-base to offshore subtidal m u d - b o t t o m
show evidence for both rapid e n t o m b m e n t of trilobites and a
e n v i r o n m e n t s influenced strongly by intermittent storms.
longer-term signature ot a cyclical increase and decrease in c a r -
T h e blue-gray m u d s t o n e s o f the overlying Kashong M e m b e r
bonate within the sediment. Trilobites frequently o c c u r in clus-
generally are rather sparsely fossiliferous but contain an a b u n -
ters of up to 100 individuals. Small-scale cyclicity, apparent in
dance of trace fossils. However, local patches within these m u d -
the lower Centerfield and in the lower W a n a k a h trilobite beds,
stones
suggests possible climatic oscillations that controlled the c a r b o n -
b r a c h i o p o d s of the
ate content of the offshore m u d s .
c h i o p o d bivalves, crinoids, bryozoans, and trilobites. Probably the
display
exceptionally
well-preserved
fossils,
including
Tropidoleptus fauna, various species of bra-
T h e highest unit of the Ludlowville F o r m a t i o n in western New
m o s t f a m o u s p o r t i o n of the Kashong is the " R e t s o f b e d s " found
York is the Jaycox M e m b e r , a richly fossiliferous m u d s t o n e . T h e s e
in the excavations for a railroad near the f o r m e r Retsof salt mines
beds are sources of high-diversity fossil assemblages very similar
in Livingston C o u n t y . T h e s e beds have been a prolific source of
THE
112 crinoids and blastoids a n d , again, relatively large s p e c i m e n s of the trilobites
Eldredgeops,
Greenops,
and
PALEOZOIC
GEOLOGY
OF
NEW
YORK
T h e Tully was preceded by an interval ot substantial erosion of the older seafloor sediments. Evidence from the u n c o n f o r m i t y
Monodechenella.
T h e highest m e m b e r o f the H a m i l t o n G r o u p , the W i n d o m
surface itself suggests that the seafloor was buckled into a series
Shale, has m a n y features similar to the m i d Ludlowville. It has
of low folded areas that b e c a m e erosionally truncated prior to and
a n u m b e r of small-scale cycles capped by beds rich in fossils of
during Tully deposition.
the typical diverse H a m i l t o n biofacies. Again, trilobites, Greenops barberi,
E.
rana,
Bellacartwrightia
sp.
and
P.
rowi,
occur
in
T h e lower p o r t i o n of the Tully L i m e s t o n e , in western New
a
York, is unusually clean, fine-grained limestone that apparently
n u m b e r of levels and are exceptionally a b u n d a n t in cyclically
accumulated in very-shallow-water c o n d i t i o n s . It contains an
bedded, calcareous m u d s t o n e s a n d argillaceous limestones that
unusual assemblage of b r a c h i o p o d s , most species of which are not
form a n o t h e r series similar to the " t r i l o b i t e b e d s " of the lower
c o m m o n to the H a m i l t o n G r o u p below. In addition, the typical
Wanakah. O t h e r p o r t i o n s of the W i n d o m Shale display the low-
H a m i l t o n trilobites and a few o t h e r species are f o u n d rarely in the
diversity, leiorhynchid b r a c h i o p o d - r i c h , dark shale facies, and
lower part of the Tully. An undescribed m e m b e r of Asteropyginae
Ambocoelia biofacies in m e d i u m gray m u d s t o n e s that are often
has been collected from this lower p o r t i o n of the Tully. It is not
highly enriched in phacopid trilobites, and c o r a l - r i c h beds that
a Greenops species, as previously reported. However, it is very
display a diversity of f o r m s including proetids, the unusual trilo-
similar to a species f o u n d in the C e d a r Valley Limestone of Iowa.
bite
A m i n o r u n c o n f o r m i t y separates these lower limestone beds from
Australosutera
gemmaea,
and
the
occurrence
of
Phacops?
iowensis.
the upper Tully. At Bellona, Yates County, apparently truncated
T h e trilobite distribution in the H a m i l t o n shows b o t h stasis, little change over a long period of t i m e , and significant change in
algal stromatolites have been found at this surface, suggesting a substantial period of shallowing, followed by erosion.
Bellacartwrightia
T h e upper portion of the Tully, a relatively clean limestone
genera show species c h a n g e , often after a transgression (Lieber-
resembling the m u c h older O n o n d a g a , displays a fauna of recur-
the
case
of
the
Asteropyginae.
Greenops
and
m a n n and Kloc 1 9 9 7 ) . O n e Kennacrypheus species makes only a
rent H a m i l t o n f o r m s . M o s t of the c o m m o n species within the
b r i e f appearance, and there are n o w still undescribed species to
upper Tully are f o r m s also present to abundant within the Hamil-
be accommodated.
ton G r o u p shales below. T h e return of trilobite bed facies is quite
T h e c o m p l e t e listing o f H a m i l t o n G r o u p trilobites follows:
evident.
The
trilobites
P.
rowi,
Bellacartwrightia
sp.,
Eldredgeops
norwoodcnsis, and Greenops? sp., as well as small rugose corals that Australosutura Bellacartwrightia
gemmaea
Bellacartwrightia
jennyi
Bellacartwrightia
calderonae
appears to be associated with a small patch reef facies found near
phyllocaudata Bellacartwrightia Cyphaspis Dipleura
Dechenella
sp.
Harpidella Phacops?
macrocephala
Pseudodechenella
Mystrocephala Proetus
iowensis arkonensis
the Tully, in total, are as follows: harrisae
ornata
baccata
jejunus
Pseudodechenella
to represent the last stand for most c o m m o n Hamilton genera and for their particular associations of biofacies. T h e trilobites of
grabaui
Kennacryphaeus
craspedota
Monodechenella
crassituberculatus rana
Greenops
barberi
in o t h e r beds in the upper part of the Tully. T h e upper Tully seems
haldemani
Eldredgeops
norwoodcnsis
Skaneateles at B o r o d i n o , O n o n d a g a County, but may o c c u r rarely
sp.
Eldredgeops
dekayi
Eldredgeops Greenops
Bellacartwrightia
whiteleyi
typify the H a m i l t o n calcareous "trilobite beds," o c c u r in several beds of the upper Tully. T h e unusual trilobite Scutellum tullius
rowi
New Asteropyginae referred to as Greenops Bellacartwrightia sp.
Eldredgeops
Harpidella spinafrons
Monodechenella
norwoodcnsis
Pseudodechenella rowi
Scutellum
macrocephala
tullius
In western New York west of Canandaigua Lake, the Tully
Tully L i m e s t o n e T h e shales o f the M o s c o w F o r m a t i o n are u n c o n f o r m a b l y over-
L i m e s t o n e has been removed, probably by deep seafloor erosion
lain throughout central New York by the unusual fine-grained
and c o r r o s i o n of the carbonates in undersaturated water. In these
( m i c r i t i c ) limestone o f the Tully F o r m a t i o n (Figures 4 . 4 1 , 4 . 4 2 A
areas, the black G e n e s e o Shale rests u n c o n f o r m a b l y on the upper
and 4 . 4 3 ) . 'The Tully is a rather e n i g m a t i c l i m e s t o n e , as it
beds of the H a m i l t o n G r o u p . However, in most localities local-
f o r m e d at a t i m e of general substantial siliciclastic input to the
ized small lenses, up to 10 or 2 0 c m thick, of reworked fossil b o n e
Appalachian Basin. It is suggested that the d e v e l o p m e n t of m i n o r
and pyrite material are observed intermittently at this contact.
folds on the sea b o t t o m in central New York ( n e a r C h e n a n g o
T h e s e beds of the Leicester Pyrite do contain occasional enrolled
Valley, C h e n a n g o C o u n t y )
served to e n t r a p m o s t siliciclastic
trilobites. W h a t is m o s t unusual about these trilobites is not
sediment that was still being shed from the second tectophase of
simply that they are pyritized, but that they are probably clasts
the Acadian O r o g e n y and to prevent these s e d i m e n t s from m o v -
removed by erosion of the underlying shale and reworked into
ing westward.
the lag deposits represented by the Leicester Pyrite.
FIGURE 4 . 4 1 . D e v o n i a n s u c c e s s i o n s . A. Devonian s u c c e s s i o n at Lake Erie. Lowest b e d s are W a n a k a h Shale (a) ( M i d d l e D e v o n i a n Ludlowville Formation). A distinctive limestone l e d g e , Tichenor M e m b e r (b), marks the b a s e of the M o s c o w Formation, w h i c h is overlain by gray W i n d o m Shale (c). A s e c o n d thin limestone, G e n u n d u w a (d), marks the a p p r o x i m a t e position of the M i d d l e - U p p e r D e v o n i a n b o u n d a r y dark gray to black shale (e) at a b o u t a third of the cliff height. Higher b e d s s h o w an alternation of black West
River-Middlesex-medium
gray,
concretion-bearing
Cashaqua
Shale
(f),
and
finally
black
Rhinestreet Shale (g) at the top of the cliff. Lake Erie Shore south of Eighteen Mile Creek, Evans, Erie County. B. M i d d l e Devonian Ludlowville a n d M o s c o w Formations (Hamilton G r o u p ) . Main cliff b e l o w the falls is the W a n a k a h a n d J a y c o x shales. Lower limestone of the falls c a p is the Tichenor M e m b e r (a) (marking the b a s e of the M o s c o w Formation), w h i c h is overlain by 2 m of D e e p Run Shale (b). The falls are c a p p e d by the Menteth Limestone (c). The b a n k a b o v e the falls is gray K a s h o n g Shale (d). Wheeler Falls, J a y c o x Creek, north of G e n e s e o , Livingston County.
FIGURE 4.42. M i d d l e D e v o n i a n / U p p e r Devonian s u c c e s s i o n s . A. M i d d l e Devonian s u c c e s s i o n . W i n d o m Shale (a) ( M o s c o w Formation, Hamilton G r o u p ) , b e l o w l e d g e s , is u n c o n f o r m a b l y overlain by t h i c k - b e d d e d Tully Limestone (b). T a u g h a n n o c k Creek, T r u m a n s b u r g , Tompkins County. B. M i d d l e - U p p e r Devonian s u c c e s s i o n . The b a s e of the falls is slightly a b o v e the Tully limestone. The main falls f a c e is G e n e s e o Shale (a). The falls are c a p p e d by the Lodi b e d s (b) of the S h e r b u r n e Formation, near the M i d d l e - U p p e r D e v o n i a n boundary. Higher cliffs are in the Penn Yan (c) (Sherburne) a n d Renwick Shale of the U p p e r D e v o n i a n . T a u g h a n n o c k Falls, T r u m a n s b u r g , Tompkins County.
DEVONIAN
PERIOD
115
FIGURE 4.43. Stratigraphy of the U p p e r Devonian a n d the u p p e r M i d d l e Devonian of N e w York. From Sevon a n d W o o d r o w (1985), after Rickard (1975).
Late Devonian Strata
prograded or built seaward into deepened basins of central New York a n d elsewhere. T h e deep basin again implies a period of
During tectophase III in the late M i d d l e - e a r l y Late D e v o n i a n ,
tectonic thrust loading that caused flexure of the crust through-
the basal c a r b o n a t e (Tully L i m e s t o n e ) gave way to black shales
out m u c h of western and central New York. T h a t basin center
(Genesee facies). T h i s was followed by a general progradation of
migrated abruptly westward f r o m its position in late Middle
siltstone, sandstone (prodelta, Portage facies; deltaic platform;
D e v o n i a n (Tully) t i m e , w h e n it lay close to the C h e n a n g o Valley
C h e m u n g facies), and red beds (subaerial delta p l a t f o r m ; Catskill
region. T h e black shales of this tectophase are actually still of
facies) (Figures 4 . 3 4 and 4 . 4 3 ) .
M i d d l e D e v o n i a n (Givetian) age in western and central New York.
Upper Devonian strata o c c u p y m o s t of the southern tier of
T h i s black m u d deposition represents the greatest deepening
New York State and are up to 2 km thick. To the east they are rep-
during the entire D e v o n i a n an event referred to as the Taughan-
resented by red siliciclastic m u d s , silts, and coarse c o n g l o m e r a t e s
nock onlap or transgression. T h e basal G e n e s e o Shale is charac-
that cap s o m e of the high peaks in the Catskill E s c a r p m e n t . T h e s e
terized by the black shales b u t displays intervals of gray, marly,
muds and conglomerates represent both m e a n d e r i n g and braided
calcareous m u d s t o n e s and thin limestones. Fossils tend to be
stream facies that accumulated rapidly in a subsiding basin in
quite scarce in these beds, presumably because of the strongly
front of a rising set of Acadian M o u n t a i n s . T h e abrupt increase
dysoxic
in siliciclastics near the base of the Upper D e v o n i a n , in associa-
prevailed on the m u d d y seafloor through most of this time.
(reduced
oxygen
fragments,
level)
goniatites,
to
anoxic
nautiloids,
conditions and
that
tion with the abrupt deepening of the basin to the west and the
Driftwood
occurrence of very widespread black shales, signals the onset
are c o m m o n in s o m e beds. Trilobites are extremely rare in the
conodonts
of the third and largest tectophase of the Acadian Orogeny.
Genesee and higher f o r m a t i o n s o f the Upper Devonian.
This m a j o r m o u n t a i n - b u i l d i n g pulse was the source of the vast
T h e base o f the Frasnian Stage o f the Upper Devonian occurs
Catskill deltaic c o m p l e x , an e n o r m o u s set of clastic wedges that
high within the Genesee F o r m a t i o n . T h e basal beds of the Frasn-
THE
116
PALEOZOIC
GEOLOGY
OF
NEW
YORK
ian are typically siltstones alternating with m e d i u m gray m u d -
Acadian Orogeny. Eventually it was sorted out that these facies
stones. T h e s e beds, like the G e n e s e e below, pass eastward into
were d i a c h r o n o u s , older to the east.
m u c h coarser-grained siltstone and sandstone facies within the
W h y did discrete tectophases o c c u r and why did the locus
Finger Lakes that, in t u r n , pass into massive m a r i n e sandstones
of basins shift southwestward? T h e Laurentia-Avalonia collision
with c o q u i n a (shell a c c u m u l a t i o n s ) . T h e Sonyea and West Falls
was mainly c o m p l e t e d by Middle to early Late Devonian, with
( I r o u p s make up the r e m a i n d e r of the Frasnian Stage. S o m e beds
rotational scissor-like closure and different p o r t i o n s of the Avalon
within the silty facies contain a b u n d a n t c o q u i n a s of b r a c h i o p o d s
t e r r a n e s hitting different p r o m o n t o r i e s of the Laurentian margin.
and clams. However, corals, b r y o z o a n s , and trilobites are only rarely seen within these beds.
O n l y a few fragments of phacopids, possibly E. rana, have been f o u n d in the G e n e s e o . T h e s e black shales pass eastward into gray
Most environmental interpretations o f the facies o f the Upper
m u d s t o n e and siltstone, with a somewhat m o r e diverse b r a c h i o -
Devonian follow the m o d e l of a delta. In the deepest most off-
pod fauna. Trilobites were never again c o m m o n within the
shore setting, fine-grained siliciclastic m u d s and a fairly large
Devonian of New York.
a m o u n t of organic detritus settled out in quiet waters. Black shale facies record these settings. Eastward of this, the seafloor sloped
T h e r e are o n l y two trilobites unique to the Upper Devonian in New York:
upward from deep water to near s t o r m wave-base (a few tens of meters of w a t e r ) , and this area is s o m e t i m e s termed the prodelta
Scutellum senescens
Otarion? laevis
region. T h i s sloped area e x p e r i e n c e d generally quiet water c o n ditions with settle-out o f f i n e m u d s , b u t episodically s t o r m o r
Reports
seismic s h o c k p h e n o m e n a generated sediment-filled turbidity
because the beds in which they were found are now possibly part
currents that laid down a series of flaggy and fine-grained sand-
o f the upper Middle Devonian.
of Eldredgeops
and
Greenops
species
are
questionable
stones with flute casts and drag marks on their lower surfaces.
C h e m u n g - s h e l f e n v i r o n m e n t s appear very similar to silty and
Such marks indicate that current directions were mainly out of
sandy p o r t i o n s of the older H a m i l t o n G r o u p . Therefore, it is
the southeast.
s o m e w h a t surprising that m a n y characteristic Hamilton species
Still farther east, the equivalent sandstones with shell c o q u i n a s
including the trilobite D. dekayi are completely absent from the
suggest deposition near or slightly above s t o r m wave-base and
Upper Devonian p o r t i o n s of the successions. Indeed, trilobites are
approaching n o r m a l wave-base. T h e s e facies have been termed
rare in almost all facies of the Upper D e v o n i a n . An extinction near
the "Chemung facies" and are interpreted as representing a s u b -
the end of the M i d d l e Devonian eliminated many of the typical
marine delta platform. O b v i o u s l y the red beds with their c h a n n e l
H a m i l t o n species and permitted an abrupt overturn to the typical
sands ("Catskill f a c i e s " ) , which are the final facies to the east, rep-
Genesee faunas of the latest M i d d l e Devonian to earliest Late
resent a n o n m a r i n e , subaerially exposed alluvial plain, perhaps a
Devonian age. A m o n g the o r g a n i s m s that were decimated locally
tidal-flat setting, in part.
by the M i d d l e Devonian e x t i n c t i o n s were the trilobites and many,
T h e westward m i g r a t i o n of these facies through the Upper
if not m o s t , of the associated rugose corals. H e n c e , the gray silty
Devonian is quite d r a m a t i c , with the red beds eventually c o m -
a n d sandy sandstone and m u d s t o n e facies that occupy so m u c h
ing to be deposited as far westward as the Genesee Valley region.
of the southern tier, although a rich source of brachiopods,
T h e fact that these individual facies transcend or cut time lines
bivalves, and o t h e r mollusks, are very p o o r for trilobite material.
established within the deltaic c o m p l e x indicates that the delta
Trilobites were clearly on the wane by the end of the Devonian,
was prograding or building forward into the seaway. As it did so,
and that last part of their history is obscure in New York State.
each successively m o r e shoreward facies built " p i g g y b a c k " over
M a r i n e ecosystems show intervals of relative stability p u n c -
the top of the next most-seaward facies, yielding a generally
tuated by abrupt turnovers at several apparently global events,
shallowing-up pattern. However, this simplistic m o d e l of a p r o -
each associated with widespread anoxia and possible climatic
grading delta must be modified in s o m e ways. For e x a m p l e , we
changes in Earth's history. D u r i n g the Late Devonian (Frasnian-
know there were intervals, probably associated with m a j o r events
F a m e n n i a n stage b o u n d a r y ) , o n e such mass extinction wiped out
causing a rise in sea level, when dark shales were spread widely
a b o u t 2 5 % o f m a r i n e families; decimated reef-building corals and
both over the prodelta slope facies and over the C h e m u n g - s h e l f
s t r o m a t o p o r o i d s ; and caused extinction of cystoids and pen-
environments.
tamerid and atrypid (orders) b r a c h i o p o d s , most a m m o n o i d s , and
T h e Appalachian Basin shifted southwestward as progressively
most r e m a i n i n g trilobites. T h e terrestrial system was not so dras-
Albany-Chattanooga)
tically affected. T h e causes of the events remain unclear. Like
spread into the Midwest. T h i s pattern was recognized in the m i d
o t h e r mass e x t i n c t i o n episodes, the Late Devonian crisis seems to
1900s as the pattern of basin filling-overfilling by deltaic p r o -
have involved sea-level
gradation of the great Catskill Delta, the flysch-molasse of the
climate stress.
younger
black
shales
(Cleveland-New
fluctuation, widespread hypoxia, and
5
The Trilobites
In this chapter, all the trilobites of New York State k n o w n to us
h o l o t y p e , such as c o t y p e , appear as they are on the label. W h e n -
are listed by family. T h e listing is first by order, with the orders
ever geographic data such as the presence of the species outside
appearing in the same sequence used in the classification chapter
New York are k n o w n to us, they are given.
of the Treatise (revised): Agnostida, Redlichiida, C o r y n e x o c h i d a ,
W h e n the t e r m type species is given at the b e g i n n i n g of the
Lichida, Phacopida, Proetida, Asaphida, and Ptychopariida (see
descriptive paragraph, it indicates that this species was used to
also Fortey, 2 0 0 1 ) . T h e families are listed alphabetically within
define the genus. In those instances where there m a y be difficul-
their respective order. S o m e New York trilobites m e n t i o n e d in the
ties in identifying similar trilobites, the diagnostic characteristics
literature did not have the a u t h o r or publication listed, and a
are presented in tabular f o r m . An asterisk b e f o r e the n a m e indi-
limited search for this i n f o r m a t i o n was unsuccessful. T h e s e trilo-
cates that the n a m e is no longer valid. T h e s e n a m e s were included
bites are listed, however, for completeness.
because they are represented in m u s e u m s or often listed in the
T h e location
information
includes
the
county,
and
only
literature.
New York counties are m e n t i o n e d . We did not a t t e m p t to m a k e this location i n f o r m a t i o n all-inclusive; thus, for m o s t species, it is only representative. M a n y New York trilobites can be f o u n d wherever the appropriate rock unit is exposed. We identified the trilobites by surveying the literature and by going through the collections of a few m a j o r m u s e u m s . T h e referenced m u s e u m s are the A m e r i c a n M u s e u m of Natural History ( A M N H ) ; Canadian Geological Survey ( O t t a w a )
(GSC);
Carnegie M u s e u m i n Pittsburgh ( C M ) ; M u s e u m o f C o m p a r a t i v e Zoology
at
Harvard
History
(USNM),
Natural
History
Museum
(MCZ);
sometimes Museum
(Natural History))
National
Museum
called just " t h e
of
London
o f Natural
Smithsonian";
(formerly
the
British
( B M ) ; New York State M u s e u m
( N Y S M ) ; Paleontological Research Institution ( P R I ) ; Peabody
5.1 ORDER AGNOSTIDA T h e agnostids are small trilobites, usually less than 12 mm (0.5 inch) long, characterized by having cephala and pygidia of a b o u t the s a m e size and never m o r e than two or three thoracic segments. T h e r e are two suborders, Agnostina and Eodiscina. In the past, s o m e workers considered the Agnostida as a different a r t h r o p o d class than trilobites, but current thinking is that they are indeed part of the class Trilobita. Agnostids are found from the C a m b r i a n through the O r d o v i c i a n , but in New York they have only been reported f r o m the C a m b r i a n rocks, primarily the a l l o c h t h o n o u s rocks on the western edge of the Taconics. T h e o r d e r is significantly revised in Treatise (revised).
Museum at Yale ( Y P M ) ; Rochester M u s e u m and Science C e n t e r ( R M S C ) ; Royal O n t a r i o M u s e u m ( R O M ) ; Buffalo M u s e u m o f
Suborder Agnostina
Science ( B M S ) ; O h i o State University ( O S U ) ; San Diego Natural History
Museum
(SDMNH);
and
University
of
Michigan
T h e agnostins have no eyes, two t h o r a c i c segments, and no facial sutures. T h e pygidium has three or fewer axial rings. As is
M u s e u m o f Paleontology ( U M M P ) . W h e n k n o w n , the location
so
of the holotype is given, but in most instances only the location
are u n k n o w n . Table 5.1 lists the families and species within this
of representative specimens is given. Any designations o t h e r than
suborder.
often
the
case
with
agnostids,
the
thoracic
segments
117
118
THE
TRILOBITES
Table 5 . 1 . Trilobites of the suborder Agnostina FAMILY
NAME
SPECIMENS
LOCATION
Diplagnostidae
Baltagnostus angustilobus (Rasetti, 1967) Baltagnostus stockportensis (Rasetti, 1967)
Holotype USNM 156565 Holotype USNM 156567
Middle Cambrian, Nutten Hook, Columbia County; see Bird and Rasetti (1968, p. 32). Middle Cambrian, Stockport Station, Columbia County; see Bird and Rasetti (1968, p. 26).
Peronopsidae
Peronopsis evansi (Rasetti and Theokritoff, 1967) Peronopsis primigenea (Kobayashi, 1939)
Holotype MCZ 8546 Lectotype USNM 18328
Lower Cambrian, Washington County, New York.
Ptychagnostidae
Ptychagnostus gibbus (Linnarsson, 1869) Ptychagnostus punctuosus (Angelin. 1851)
Plesiotypes USNM 156552, 156553 Plesiotypes USNM 156551
Middle Cambrian, Columbia County; see Bird and Rasetti (1968. p. 11). Type species. Middle Cambrian, Columbia County; see Bird and Rasetti (1968, p. 28).
Spinagnostidae
Eoagnostus acrorachis (Rasetti and Theokritoff, 1967) Eoagnostus primigeneus (Kobayashi, 1939) Hypagnostus parvifrons (Linnarsson, 1869)
Holotype MCZ 8544
Lower Cambrian, West Castleton Formation, Washington County, New York.
Cotype USNM 18328 Plesiotypes USNM 156561 to 156563
Lower Cambrian.
Suborder Eodiscina Plate 1 T h e eodiscins have two or three t h o r a c i c s e g m e n t s and four o r m o r e axial s e g m e n t s o n the pygidium, and m a y b e w i t h o u t eyes or facial sutures. In the Treatise (revised), the s u b o r d e r has been significantly t a x o n o m i c a l l y revised, a n d new family struc-
Lower Cambrian, Washington County, New York.
Type species. Middle Cambrian. Columbia County; see Bird and Rasetti (1968, p. 68). The holotype is from Sweden.
5.3 ORDER CORYNEXOCHIDA Family Dolichometopidae Athabaskiella cf. A. proba
(Walcott)
Middle C a m b r i a n , S t o c k p o r t Station, C o l u m b i a County. See Bird and Rasetti ( 1 9 6 8 , p. 2 8 ) .
tures assigned. Table 5.2 lists the families and species within this Bathyuriscidella cf.
suborder.
B.
socialis
(Rasetti)
Middle C a m b r i a n , S t o c k p o r t Station, C o l u m b i a County. See Bird and Rasetti ( 1 9 6 8 , p. 2 8 ) .
5.2 ORDER REDLICHIIDA T h e redlichiids are the m o s t primitive and earliest k n o w n of the trilobites. T h e y generally have a relatively large, semicircular cephalon with long genal spines, n u m e r o u s t h o r a c i c segments, and a very small pygidium. T h e o n l y well-known m e m b e r of this order in New York is Elliptocephala asaplwides, a Lower C a m b r i a n trilobite from the s u b o r d e r Olenellina, a s u b o r d e r representing the earliest o f the k n o w n trilobites. T h e holaspids o f the olenellins do not show facial sutures.
eboracensis
(Rasetti,
1967)
Holotype U S N M 156654 Middle C a m b r i a n , S t o c k p o r t Station, C o l u m b i a County. See Bird and Rasetti ( 1 9 6 8 , p. 2 6 ) . Bathyuriscus cf. B.
fibriatus
(Robison)
M i d d l e C a m b r i a n , S t o c k p o r t Station, C o l u m b i a County. See Bird and Rasetti ( 1 9 6 8 , p . 2 8 ) .
Family Holmiidae Elliptocephala asaphoides E m m o n s ,
Bathyuriscus
Corynexochides? 1 8 4 6 Plate 2
Type N Y S M 4 9 5 4
expansus
(Rasetti,
1967)
H o l o t y p e U S N M 156651 Middle C a m b r i a n , S t o c k p o r t Station, C o l u m b i a County. See
Type species. T h i s trilobite is f r o m the Lower C a m b r i a n ,
Bird and Rasetti ( 1 9 6 8 , p. 2 6 ) .
Nassau F o r m a t i o n , Troy, Rensselaer C o u n t y . It also is reported f r o m n u m e r o u s Lower C a m b r i a n l i m e s t o n e sites in C o l u m b i a
Family Dorypygidae
C o u n t y (see Bird and Rasetti
Fordaspis nana ( F o r d , 1 8 7 8 )
1 9 6 8 ) . T h i s is an apparently
deep-water trilobite f o u n d in Lower C a m b r i a n a l l o c h t h o n o u s dark shales. T h e s p e c i m e n in Plate 2 is rust colored on a black matrix.
Hypotypes N Y S M 1 1 0 4 7 , 1 1 0 4 8 Type
species.
Goldring ( 1 9 4 3 ) .
Lower
Cambrian,
Nassau
Formation.
See
Table 5.2. Trilobites of the suborder Eodiscina FAMILY Calodiscidae
NAME Calodiscus agnostoides
(Kobayashi, 1943) Calodiscus
fissifrons
(Rasetti, 1966) Calodiscus
lobatus
(Hall, 1847) Calodiscus meeki (Ford,
1876) Calodiscus
occipitalus
(Rasetti, 1966) Calodiscus
reticulatus
(Rasetti, 1966) Calodiscus
schucherti
(Matthew, 1896) Calodiscus
theokritoffi
(Rasetti, 1967) Calodiscus
walcotti
(Rasetti, 1952) Chelediscus
chathamsis
(Rasetti, 1967) Eodiscidae
Pagetia bigranulosa
(Rasetti, 1967) Pagetia
connexa
SPECIMEN
LOCATION
Holotype USNM 116356 Holotype USNM 146004 Syntype AMNH 210 Holotype NYSM 4587 Holotype USNM 146003 Holotype USNM 146006 Syntype ROM 138 Holotype GSC 105 Holotype USNM 26710 Holotype USNM 156584
Lower Cambrian, Schodack Formation, Salem, Washington County Lower Cambrian, Columbia County. Type species. Lower Cambrian, Nassau Formation, found at Troy, Rensselaer County, and in Washington County. Lower Cambrian, Schodack Formation. Troy, Rensselaer County. Lower Cambrian, Columbia County. Lower Cambrian, Columbia County. Lower Cambrian, Schodack Formation, Troy, Rensselaer County. Lower Cambrian, Maiden Bridge roadcut, Columbia County; see Bird and Rasetti (1968, p. 11). Lower Cambrian, Schodack Formation, near Greenwich, Washington County. Lower Cambrian, Maiden Bridge roadcut, Columbia County; see Bird and Rasetti (1968, p. 11).
Holotype USNM 1566 Holotype USNM
Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Lower Cambrian, Washington County.
Holotype USNM 156615 Holotype USNM 156613 Holotype USNM 156610 Plesiotypes USNM 156632, 156633 Plesiotypes USNM 156618 Plesiotypes USNM 156626 to 156628 Plesiotypes USNM 156621 to 156625 Plesiotypes USNM 156629 to 156631
Middle Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Middle Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Lower Cambrian, Riders Mills and Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Type species. Lower Cambrian, numerous sites in Columbia County; see Rasetti (1967). Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Lower Cambrian, numerous sites in Columbia County; see Rasetti (1967). Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5).
Holotype USNM 156637 Holotype USNM 156634
Lower Cambrian, 1.6km (1 mile) east of Salem, Washington County. Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5).
Holotype USNM 145987 Holotype USNM 145989 Holotype USNM 145991 Holotype USNM 145093 Holotype USNM 156575 Holotype USNM 145955
Type species. Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Lower Cambrian, Columbia County.
(Walcott, 1891) Pagetia
clytioides
(Rasetti, 1967) Pagetia erratica (Rasetti,
1967) Pagetia laevis (Rasetti,
1967) Pagetides
amplifrons
(Rasetti, 1945) Pagetides
elegans
(Rasetti, 1945) Pagetides
leiopygus
(Rasetti, 1945) Pagetides
minutus
(Rasetti, 1945) Pagetides
rupestris
(Rasetti, 1948) Hebediscidae
Hebediscus marginatus
(Rasetti, 1967) Neopagetina
taconica
(Rasetti, 1967) Weymouthiidae
Acidiscus bird! (Rasetti, 1966) Acidiscus
hexacanthus
(Rasetti, 1966) Acimetopus
bilobatus
(Rasetti, 1966) Analox
bipunctata
(Rasetti, 1966) Analox obtusa (Rasetti,
1967) Bathydiscus dolichometopus
Type species. Lower Cambrian, Columbia County. Type species. Lower Cambrian, Columbia County. Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Type species. Lower Cambrian, Columbia County.
(Rasetti, 1966) Bolboparia
elongata
(Rasetti, 1966)
Holotype USNM 146001
Lower Cambrian, Columbia County.
120
THE
TRILOBITES
Table 5.2. Continued FAMILY
NAME Bolboparia
superba
(Rasetti, 1966) Leptochilodiscus
punctulatus
(Rasetti,
SPECIMEN
LOCATION
Holotype USNM 145998 Holotype USNM 146009
Type species. Lower Cambrian, Columbia County.
Holotype USNM 146012 Holotype USNM 18327
Type species. Lower Cambrian, Columbia County.
Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5); also found in Quebec.
1966) Litometopus
longispinus
(Rasetti, 1966) Mallagnostus
desideratus
(Walcott,
Washington County, New York. See Rasetti and Theokritoff (1967) for a discussion of this species.
i o y i)
Microdiscus?
Lower Cambrian, Nassau Formation; the genus Microdiscus is no longer used so this species is probably Eodiscus.
(Eodiscus)
connexus (Walcott,
1890) Oodiscus
binodosus
(Rasetti, 1966) Oodiscus
longifrons
(Rasetti, 1966) Oodiscus
subgranulatus
(Rasetti, 1966) Serrodiscus
griswoldi
(Rasetti, 1967) Serrodiscus
latus
(Rasetti, 1966) Serrodiscus
speciosus
(Ford, 1873) Serrodiscus
spinulosus
(Rasetti, 1966) Serrodiscus
subclovatus
(Rasetti, 1966) Stigmadiscus
gibbosus
(Rasetti, 1966) Stigmadiscus
stenometopus
(Rasetti,
Holotype USNM 146016 Holotype USNM 146018 Holotype USNM 146014 Holotype USNM 156596 Holotype USNM 146024 Lectotype NYSM 4588 (Rasetti, 1952) Holotype USNM 14602 Holotype USNM 146022 Holotype USNM 146031 Holotype USNM 146029
Lower Cambrian, Columbia County. Lower Cambrian, Columbia County. Lower Cambrian, Columbia County. Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 11). Lower Cambrian, Griswold Farm, Columbia County; see Bird and Rasetti (1968, p. 5). Type species. Lower Cambrian, Schodack Formation, Troy. Rensselaer and Washington Counties. Lower Cambrian, Maiden Bridge roadcut, Columbia County; see Bird and Rasetti (1968, p. 11). Lower Cambrian, Columbia County. Lower Cambrian, Griswold Farm and Maiden Bridge, Columbia County; see Bird and Rasetti (1968, p. 5, 11). Lower Cambrian, Griswold Farm and Maiden Bridge, Columbia County; see Bird and Rasetti (1968, p. 5, 11).
1966) Weymouthia
nobilis
(Ford, 1873)
Kootenia fordi
Plesiotype MCZ 105039
(Walcott)
Lower Cambrian, Nassau Formation, Troy, Rensselaer County. The type is from Massachusetts.
is in the Lower Silurian Rochester Shale. T h e family is characterized
Lower C a m b r i a n , Nassau F o r m a t i o n .
by a s m o o t h , vaulted cephalon with no glabellar furrows. T h e posterior of the glabella is often outlined by weakly depressed furrows.
Olenoides
stissingensis
Specimen N Y S M
(Dwight)
T h e s e furrows rarely extend to the anterior portion of the c r a n i d i u m . T h e facial sutures are o p i s t h o p a r i a n , and the eyes are broadly
17011
Stissing L i m e s t o n e , Stissing M o u n t a i n , Dutchess C o u n t y , New
set near the cephalic m a r g i n s . T h e r e are eight to ten unfurrowed
York. T h e specimen is a s a n d s t o n e slab with m a n y disarticulated
t h o r a c i c s e g m e n t s . T h e pygidium is similarly vaulted and s m o o t h .
trilobite parts.
T h e pygidium, when f o u n d separately, often resembles a dark t h u m b n a i l . Lane and T h o m a s (1983) moved a n u m b e r of f o r m e r
Olenoides stockportensis
(Rasetti,
illaenids into the family Styginidae. A large n u m b e r of species have
1967)
H o l o t y p e U S N M 156668 Middle
Cambrian,
Stockport
been described from New York, but this may well be oversplitting, Station,
Columbia
County.
particularly in the Trenton species, which need r e d e s c r i p t i o n . S h a w
See Bird and Rasetti (1968, p. 26).
(1968) redescribed most of the Chazy material.
Family lllaenidae
Bumastoides aplatus
Ulaenids are first f o u n d in the Lower O r d o v i c i a n and disappear
(Raymond,
1925)
H o l o t y p e M C Z 101150
by the end of the Silurian. In New York they are first f o u n d in the
T h i s illaenid is from Middle Ordovician Chazy. For location
lower M i d d l e Ordovician Chazy G r o u p , and the last representative
i n f o r m a t i o n , see Shaw (1968). T h e c r a n i d i u m is semicircular in
ORDER
CORYNEXOCHIDA
121
dorsal view and about half as long as wide. T h e axial furrows are
the internal cast. T h e s e pits have n o t been seen on specimens
faint. T h e t h o r a x is u n k n o w n . T h e pygidium is s m o o t h , vaulted,
f r o m l o c a t i o n s o t h e r than the W a l c o t t - R u s t Quarry. T h e speci-
and without furrows. T h e s m o o t h cephalon and pygidium differ
m e n in Plate 4 is partially exfoliated and shows, on the left side,
from all other Chazy illaenids. R a y m o n d also listed it as f r o m
the lunette and its position relative to the eye. Plate 5 is a side
Vermont and Tennessee.
view of a n o t h e r s p e c i m e n f r o m the s a m e collection, also showing the lunette.
Bumastoides?
bellevillensis
(Raymond
and
Narraway,
1908)
Type C M 1900; s p e c i m e n s M C Z 7 2 0 , 7 1 9 Both
MCZ
specimens
are
from
the
Bumastoides milleri Middle
Ordovician.
N u m b e r 7 2 0 is from the Trenton L i m e s t o n e at Sugar River, Lewis
(Billings,
1859)
Plate 6
Holotype G S C 1319b; specimens U S N M 72265; M C Z 7 2 1 , 722; PRI 6455
County, and 7 1 9 is from the Black River Limestones at Buck's
T h e h o l o t y p e is f r o m O n t a r i o . T h e s p e c i m e n s in the U S N M
Quarry near Poland, H e r k i m e r C o u n t y . B o t h are cranidia in
are f r o m the M i d d l e O r d o v i c i a n Lowville M e m b e r of the Black
C. D. Walcott's collections.
River G r o u p . T h e y are listed f r o m W a t e r t o w n , Lewis County. O t h e r s p e c i m e n s are f r o m quarries near N e w p o r t , H e r k i m e r
Bumastoides billingsi
(Raymond
and
Narraway,
1908)
County. S p e c i m e n s in the M C Z are f r o m Walcott's collections and
Type C M 5 4 7 2 , hypotype G S C 331
are labeled f r o m the Black River L i m e s t o n e s at Buck's Q u a r r y
T h e type of this species is from Hull, Q u e b e c . T h e species dif-
near Poland, H e r k i m e r C o u n t y , and f r o m the lower Trenton at
ferentiation from other similar Trenton s p e c i m e n s is based pri-
Rawlin's Mills ( n e a r Saratoga, Saratoga C o u n t y ) . D e M o t t ( 1 9 8 7 )
marily on size. T h e length, 60 and 83 m m , is m u c h greater than
listed s p e c i m e n s from Illinois and W i s c o n s i n . T h e s p e c i m e n in
that of B. trentonensis and B.
milleri; the dorsal furrows on the
cephalon are also stronger and those on the t h o r a x are wider
Plate 6 is f r o m W a t e r t o w n and was listed on the label from the Trenton G r o u p .
apart. Bumastoides porrectus Bumastoides
gardenensis
(Shaw,
1968)
(Raymond,
1925)
Plate
7
Holotype M C Z 101147
Holotype N Y S M 12456
T h e type for this M i d d l e O r d o v i c i a n trilobite is from the
This small illaenid from the Middle O r d o v i c i a n Chazy is very
W a l c o t t - R u s t Quarry, H e r k i m e r C o u n t y , in the Rust M e m b e r of
similar to B. aplatus. For location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
the T r e n t o n G r o u p . T h e species was described to replace B. tren-
Bumastoides globosus
definition. T h e cephalon has faint dorsal furrows, and the eyes
tonensis because, in the o p i n i o n of R a y m o n d , the latter has a p o o r (Billings,
1859)
Plate
3
Lectotype G S C 1 0 9 0 B (Shaw, 1968)
are situated far b a c k and wide apart. T h e t h o r a x has a wide axial
This Middle Ordovician Chazy species is defined as having
lobe and ten t h o r a c i c s e g m e n t s . T h e pygidium is s h o r t and
a wide axis, well-developed cephalic axial furrows, and a b r o a d
without a trace of an axial l o b e . T h e entire exoskeleton is s m o o t h .
s m o o t h pygidium. F o r location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
T h e h o l o t y p e is figured in Plate 7. D e M o t t ( 1 9 8 7 ) also listed B.
T h e specimen in Plate 3 is a rare, articulated s p e c i m e n from
porrectus f r o m W i s c o n s i n and Iowa. B o l t o n ( 1 9 6 6 ) listed speci-
the Chazy G r o u p . Articulated trilobites f r o m the Chazy are
m e n s from O n t a r i o and Q u e b e c .
rare, probably because the Chazy c o m m o n l y represents a highenergy e n v i r o n m e n t not conducive to the preservation of articu-
* Bumastoides
lated specimens.
Plastotype A M N H 8 4 7 ; hypotypes N Y S M 4 1 5 8 , 1 0 7 5 7
trentonensis
(Emmons,
1842)
N Y S M 4 1 5 8 is labeled as the " T y p e of G e o l o g y of New York, Bumastoides holei (Foerste,
1920)
Plates 4 and 5
Report o f the 2 n d District, 1 8 4 2 , p . 3 9 0 " and " G e o l o g i c a l Survey
Hypotype M C Z 1 0 1 1 4 8
of M i n n e s o t a , 1 8 9 6 , p. 7 2 0 , Figure 3 2 . " T h e r e is also a label with
T h e type of this species is from the Middle Ordovician Kimmswick
Limestone
of M i s s o u r i .
It
was
redescribed
by
the
specimen
for
Bumastus porrectus
Raymond.
NYSM
10757
is listed from the R o c k l a n d ( N a p a n e e ) M e m b e r of the Trenton
R a y m o n d ( 1 9 2 5 ) with material from the W a l c o t t - R u s t Quarry,
at Wells, H a m i l t o n C o u n t y ( F i s h e r ) . T h i s M i d d l e Ordovician
Herkimer
a
Trenton species was a b a n d o n e d b y R a y m o n d ( 1 9 2 5 ) because o f
cephalon m u c h larger than the pygidium. T h e cephalon is evenly
its p o o r definition. Given the existence of the hypotypes, there is
convex, with a slight longitudinal m e d i a n depression. T h e eyes
reason to question R a y m o n d ' s decision.
County.
The
specimens
from
New York
have
are small, wide apart, and close to the posterior margin. T h e r e is a small median tubercle just in front of the posterior cephalic
Illaenus
margin. T h e axial lobe of the t h o r a x is very wide. T h e t h o r a x has
Holotype N Y S M 4499
arcturus
(Hall,
1847)
ten thoracic segments. T h e pygidium has no trace of an axial lobe.
T h e type of this species, labeled from the Middle Ordovician
T h e entire exoskeleton is granulose with c o r r e s p o n d i n g pits on
Chazy G r o u p , was studied by Shaw ( 1 9 6 8 ) , w h o concluded that
122
THE
TRILOBITES
the s p e c i m e n was in too p o o r c o n d i t i o n for c o m p a r i s o n with
H e r k i m e r C o u n t y , and in the Wells Outlier, Hamilton County,
o t h e r illaenids of the Chazy. He did believe it had definite
by Fisher ( 1 9 5 7 ) . T h e specimen in Plate 9 is labeled from the
nanillaenid character and the m a t r i x was unlike any of those he
Bowmanville Q u a r r y in O n t a r i o . This would place it high in
was familiar with in the Chazy. Chazy s p e c i m e n s assigned by
Trenton age rocks.
Raymond Thaleops
(1910b)
longispina
as
Thaleops
(Shaw,
arctura
became
the
basis
for
1968).
Nanillaenus?punctatus
(Raymond,
1905)
H o l o t y p e C M 1 2 7 8 , s p e c i m e n N Y S M 17015 Illaenus consimilis ( B i l l i n g s , 1 8 6 5 )
T h i s rare middle Chazy species is o n e of the most easily char-
Specimens U S N M 72319, 72317
acterized, as the entire surface of the cephalon is covered with
U S N M 7 2 3 1 9 is from the M i d d l e O r d o v i c i a n Trenton Walcott-
small pits or p u n c t a , and the anterior slope of the cephalon is
Rust Quarry, H e r k i m e r C o u n t y , and U S N M 7 2 3 1 7 is f r o m the
covered with terrace lines so distinct that R a y m o n d referred to
Trenton at Ellisburg, Jefferson C o u n t y . T h e types are from Table
t h e m as c o n c e n t r i c wrinkles. For location i n f o r m a t i o n , see Shaw
Head, N e w f o u n d l a n d ( B o l t o n , 1 9 6 6 ) .
(1968).
Nanillaenus americanus (Billings,
1859)
Plate 8
Nanillaenus? raymondi (Shaw,
Specimens N Y S M 17013, 17014 This
Middle
Ordovician
1968)
Plate
10A
H o l o t y p e N Y S M 12491
trilobite
is
well
represented
in
Nanillaenus? raymondi from
the Middle Ordovician Chazy is
N Y S M , U S N M , and M C Z collections f r o m W a l c o t t - R u s t Q u a r r y ,
characterized as being very similar to N.? punctatus, with the
Herkimer C o u n t y , in the Middle Trenton Rust L i m e s t o n e . T h e
exception that the cephalic outline in dorsal view is subtriangu-
cephalon on this small trilobite is considerably larger than the
lar rather than semicircular and the f o r m e r possesses a spine on
pygidium. Axial furrows on the cephalon are only developed on
the tree cheek. For location i n f o r m a t i o n , see S h a w I 1968).
the posterior region. T h e eyes are set well b a c k and far apart. T h e free cheeks have a p r o m i n e n t blunt angle. T h e furrows on
Thaleops longispina
the thorax are well defined. T h e r e are eight t h o r a c i c s e g m e n t s .
H o l o t y p e N Y S M 12922
T h e pygidium has a similarly well-defined axis over half the length of the pygidium. T h e s p e c i m e n in Plate 8 is from the M C Z
(Shaw,
1968)
Plate
10B
T h i s trilobite is from the Middle Ordovician Chazy limestones.
F o r location
i n f o r m a t i o n , see
Shaw
(1968).
Thaleops
and illustrates the difference between these trilobites and Bumas-
longispina
toides s p e c i m e n s f o u n d in the s a m e rocks.
cephalon and pygidium. T h e glabella is outlined by deep furrows,
is a
short, wide trilobite with
a
broadly rounded
which are parallel for half their length and then turn outward and Nanillaenus cf. N. conradi ( B i l l i n g s ,
1859)
down on the front of the c e p h a l o n . T h e eyes are raised on tapered
Syntypes G S C 1 3 2 0 , 1 3 2 0 a ; hypotype N Y S M 1 0 7 4 9 ; s p e c i m e n
stalks, which reach up and out at about a 4 5 - d e g r e e angle. T h e r e
N Y S M 17012
are long, narrow genal spines. T h e t h o r a x has ten segments. T h e
Type species. T h i s trilobite is listed from the M i d d l e O r d o v i -
pygidial axis is outlined by deep grooves and extends about half
cian Upper Black River C h a u m o n t L i m e s t o n e in Wells, H a m i l t o n
the length of the pygidium. B o t h the c r a n i d i u m and pygidium
County, by Fisher ( 1 9 5 7 ) . T h e syntypes are from the M i d d l e
are covered with small pits.
Ordovician Leray beds o f Q u e b e c ( B o l t o n 1 9 6 6 ) . Thaleops Nanillaenus latiaxiatus ( R a y m o n d a n d Narraway, 1 9 0 8 ) Plate 9 Type C M 5471
ovata
(Conrad,
1843)
Holotype A M N H 1011/3 Type species. T h e type is from W i s c o n s i n , in rocks with fossils
T h e type is from the M i d d l e O r d o v i c i a n Black River L i m e -
that are clearly Middle Ordovician Trenton age (Hall, 1 8 4 7 ) .
stones at Mechanicsville, near O t t a w a , C a n a d a . R a y m o n d and
Reports of T. ovata from the Chazy of New York are wrong (see
Narraway
Shaw 1 9 6 8 ) . R u e d e m a n n ( 1 9 0 1 ) found two pygidia in a gray crys-
suggested
that
many
of
the
Nanillaenus
americanus
specimens reported from the Black River are this species. T h e
talline limestone within the Rysedorph C o n g l o m e r a t e that agreed
species is similar to the latter trilobite except in the t h o r a x and
with the descriptions of 7! ovata. He also stated that specimens
the pygidium. T h e t h o r a x has ten segments, versus eight in N.
like those of T. ovata from other areas outside New York are found
americanus. T h e pygidium is about as long as the t h o r a x , s o m e -
in strata c o r r e s p o n d i n g to the Black River Lowville Limestone.
what rectangular in outline, three-fifths long as wide. T h e sides
D e M o t t ( 1 9 8 7 ) listed T. ovata from Illinois and W i s c o n s i n .
of the pygidium are abruptly t r u n c a t e d to right angles with the anterior margin. T h e axial lobe is strongly convex and outlined
Family Styginidae
by deep furrows on the sides. T h e axial lobe is a b o u t half the
Lane and T h o m a s ( 1 9 8 3 ) revised the family Styginidae to
length of the pygidium. T h i s trilobite is reported in the Black
include the family Thysanopeltidae and s o m e illaenids. T h e
River rocks at Pattersonville, Schenectady C o u n t y , and N e w p o r t ,
genus Bumastus is now considered a styginid. Holloway and Lane
ORDER
CORYNEXOCHIDA
123
( 1 9 9 8 ) , however, consider that of the New York trilobites assigned
genus Illaenoides and the trilobites he describes from Wisconsin
to Bumastus, only Bumastus ioxus is assigned with
do not differ from those f o u n d in the Rochester Shale.
confidence.
Styginids are rarely e n c o u n t e r e d in New York. In general, the glabella expands strongly forward, the genal angle is acute, the
Platillaenus
pleurae have narrow spines beyond the edge of the t h o r a x ,
L e c t o t y p e Y P M 7 4 1 0 A (Shaw, 1 9 6 8 )
and the pygidium is large and the back of the a n t e r i o r edge is
erastusi
(Raymond,
1905)
T h i s trilobite a n d the following P.
limbatus are from the
oval. T h e y are f o u n d from the Middle O r d o v i c i a n to the Upper
Middle O r d o v i c i a n Chazy G r o u p . See Shaw ( 1 9 6 8 ) for detailed
Devonian.
descriptions and locations.
Bumastus ioxus (Hall, 1 8 5 2 ) Plate 11
Platillaenus
Holotype A M N H 1821/1
L e c t o t y p e Y P M 2 3 3 0 1 (Shaw, 1 9 6 8 )
T h e holotype for B. ioxus is from W i s c o n s i n , a n d the specimens from the Lower Silurian Rochester Shale in western New
limbatus
(Raymond,
1910)
Middle O r d o v i c i a n Chazy G r o u p . For location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
York have long been assigned to this species. Small whole specimens are often found, s o m e t i m e s in groups, in the lower parts of
Scutellum
the Lewiston M e m b e r in Niagara C o u n t y (Tetreault 1 9 9 4 ) . T h i s
Type N Y S M 4 1 4 9
trilobite is s m o o t h and oval. T h e cephalon has widely spaced eyes. T h e axial furrows are faint and fade toward the front. T h e pygid-
barrandi
(Hall,
1859)
An undisclosed location in the Lower D e v o n i a n C o e y m a n s Limestone.
ium has a semicircular shape. T h e specimen in Plate 11 is m u c h larger than those usually f o u n d . T h e large s p e c i m e n s and the
Scutellum
smaller ones are found in different h o r i z o n s within the R o c h e s t e r
H o l o t y p e A M N H 1830
Shale. Compression due to the weight of the overlying sediments has flattened the s p e c i m e n , causing the edges of the cephalon and pygidium to crack.
niagarensis
Scutellum
(Hall,
1852)
Plate
16
niagarensis was originally f o u n d in a float boulder
at Niagara Falls, Niagara C o u n t y . O n l y the pygidium was originally described. T h e pygidium is very b r o a d and semicircular. Plate 16 also shows the previously undescribed c e p h a l o n . It is also
Eobronteus lunatus (Billings,
1857)
Plate
reported from the M i d d l e Silurian Reynales L i m e s t o n e in Wayne
12
Holotype G S C 1 7 8 1 , hypotype N Y S M 4 1 5 0 , s p e c i m e n N Y S M
C o u n t y (Gillette 1 9 4 7 ) .
17016 Ruedemann ( 1 9 0 1 ) reported this species f r o m M i d d l e O r d o v i cian Trenton pebbles in the Rysedorph C o n g l o m e r a t e , Rensselaer County. It is geographically widely distributed, being reported
Scutellum
pompilius
(Billings,
1863)
G o l d r i n g ( 1 9 4 3 ) listed this species as f r o m the Lower Devonian Kalkberg in C o l u m b i a C o u n t y .
from C a n a d a , M i n n e s o t a , and New Jersey. T h e h o l o t y p e is f r o m the Middle Ordovician of O n t a r i o . T h e specimen in Plate 12 is
Scutellum rochesterense (Howell a n d S a n f o r d ,
from Snake Hill Shales in Saratoga C o u n t y .
H o l o t y p e Princeton University 5 7 6 9 6 a ( n o w U S N M ) Lower
Failleana
indetermitiata
(Walcott,
1877)
Plate
13
Silurian
Irondequoit
Limestone
1946)
Plate 2 6 B
of the
Rochester,
M o n r o e C o u n t y , area.
Holotype M C Z 1 0 4 9 2 8 T h e holotype is from the Middle O r d o v i c i a n Black River Group limestone at Buck's Q u a r r y , Poland, H e r k i m e r County.
Scutellum senescens ( C l a r k e ,
1889)
Plate
17
H o l o t y p e N Y S M 4 1 5 1 ; hypotypes N Y S M 4 1 5 2 , 4 1 5 3
T h e relatively large type specimen was figured for the first t i m e
Upper Devonian C h e m u n g o f western New York. T h e hypo-
by R a y m o n d ( 1 9 1 6 ) and is shown in Plate 13. T h e s p e c i m e n is
type s p e c i m e n s were f o u n d while recovering the glass sponge
from the Walcott collection at M C Z . W i l s o n ( 1 9 4 7 ) reported the
Hydnoceras
trilobite from the lower Trenton Rockland beds of C a n a d a .
County. Trilobites are very rare in the Upper Devonian of New
from
a
Chemung
outcrop
near
Avoca,
Steuben
York, and the o n e illustrated in Plate 17 is an excellent example Illaenoides cf. /. trilobita (Weller, 1 9 0 7 ) Plates 14 a n d 15
of a very u n c o m m o n species.
Hall and Clarke ( 1 8 8 8 , plate 6 6 , Figures 1 - 5 ) T h e presence of a second illaenid in the Lower Silurian Rochester Shale, other than Bumastus ioxus, was long u n r e c o g nized.
Illaenoides
trilobita
is
easily
differentiated
Scutellum tullius (Hall a n d C l a r k e , 1 8 8 8 ) Plate 18 Syntypes N Y S M 4 1 5 4 , 4 1 5 5
by the c o m -
Middle Devonian Tully L i m e s t o n e . N Y S M 4 1 5 4 is from Kings-
paratively larger cephalon and the distinctive b o r d e r on the
ley's Hill near Otisco, O n o n d a g a C o u n t y . S p e c i m e n s are reported
pygidium, and the axial furrows on b o t h the cephalon and the
f r o m a q u a r r y near Spafford, O n o n d a g a County. C o o p e r and
pygidium are well defined. Weller ( 1 9 0 7 ) first recognized the new
W i l l i a m s ( 1 9 3 5 ) described the trilobite and listed a n u m b e r of
THE
124
TRILOBITES
locations. T h e illustrated s p e c i m e n s were f o u n d by Professor
William Rust. It is probable that the specimen is from the
Wells of Cornell University and the r e c o n s t r u c t i o n is an u n p u b -
W a l c o t t - R u s t Q u a r r y , H e r k i m e r County. R u e d e m a n n c o m p a r e d
lished drawing of his.
this s p e c i m e n to A. halli ( U p p e r O r d o v i c i a n , O h i o ) and found significant differences. He m a d e no c o m p a r i s o n s with any of
Scutellum wardi (Howell and S a n f o r d ,
1947)
the New York amphilichids. R u e d e m a n n did report evidence that
Holotype U S N M 488132
the h o l o t y p e c r a n i d i u m was covered with thin spines, an obser-
T h e type is a single pygidium f r o m the Upper Silurian O a k Orchard
M e m b e r o f the L o c k p o r t G r o u p
vation not reported in any of the other New York amphilichids
i n the Rochester,
n o r does it appear to be supported by our own examination of
M o n r o e County, area. T h e axis is very s h o r t , and the entire
the h o l o t y p e and o t h e r specimens. T h e glabella has a low
surface is s m o o t h .
rounded shape quite different from that of A. cornutus. T h e illustrated pygidium from R u e d e m a n n ( N Y S M 9 6 0 8 ) differs from A.
Family Zacanthoididae Prozacanthoides
eatoni
cornutus in that the pygidal lappets closest to the axis are drawn
(Walcott,
1891)
as forked on their ends. ( C l o s e e x a m i n a t i o n of the paratype does
Holotype U S N M
not appear to support this c o n c l u s i o n that the pygidial lappets
Lower C a m b r i a n , W a s h i n g t o n C o u n t y , New York.
are forked.) T h e h o l o t y p e is identical to specimens in the M C Z , f r o m the W a l c o t t - R u s t Q u a r r y , c o n f i r m i n g that N Y S M 9 6 0 7 is a
5 . 4 ORDER LICHIDA Family Lichidae
different species than A. cornutus.
Trilobites of the family Lichidae are first f o u n d in the Lower Ordovician and disappear at the end of the D e v o n i a n . In New
Amphilichas cornutus
(Clarke,
1894)
Plate
19
Holotype N Y S M 4533; specimens U S N M 2 6 3 4 1 , 72629
York they range f r o m the M i d d l e O r d o v i c i a n to the M i d d l e
T h e h o l o t y p e , illustrated in Plate 19, is an articulated speci-
D e v o n i a n . Lichids are very distinctive in their glabellar outline
m e n that was badly damaged during the preparation. It does
with two p r o m i n e n t lateral lobes, which because they are so dis-
have a p r o m i n e n t , c o n e - s h a p e d glabella. T h e pygidium is intact,
tinctive are given their o w n n a m e , bullae. Figure 5.1 shows lichid
however, and serves, along with the glabella shape, as a p r i m a r y
cephala with the distinctive bulla. Lichids are c o m m o n n o w h e r e ,
identifying feature. A c r a n i d i u m with this n a m e in the U S N M
b u t in certain h o r i z o n s their characteristic exuviae can be f o u n d
( U S N M 2 6 3 4 1 ) is pustulose. T h e location for the holotype is
by carefully searching. T h e lichids range in size f r o m the quite
given as Trenton Falls, which encompasses the entire middle
small Hemiargespaulianus ( 1 0 to
15 m m ) to the large and heavily
T r e n t o n ; however, the location label indicates the specimen was
o r n a m e n t e d Terataspis grandis (> 30 c m ) . W h o l e s p e c i m e n s of the
purchased from William Rust. Since most of Rust's material
lichids are rare and very prized by b o t h m u s e u m s and collectors.
c a m e f r o m the M i d d l e Ordovician Trenton Walcott-Rust Quarry,
T h o m a s and Holloway ( 1 9 8 8 ) extensively reviewed the classifica-
H e r k i m e r C o u n t y , and o t h e r s p e c i m e n s have been f o u n d there, it
tion and phylogeny, b u t the New York species need revision.
is likely that the h o l o t y p e is from that location. T h e U S N M speci m e n 7 2 6 2 9 has a " m u s e u m label" n a m e . It is a p r o m i n e n t glabella
Acanthopyge
(Lobopyge)
consanquinea
(Clarke,
1894)
f r o m the Middle Ordovician Trenton Limestone near Trenton
Figure 5 . I D
Falls. T h e p r o m i n e n t glabella indicates it is most likely A. cornu-
Holotype N Y S M 4 5 3 0
tus. Labels of material like this from " n e a r Trenton Falls" often
A lichid f r o m the Lower D e v o n i a n New Scotland L i m e s t o n e
m e a n the W a l c o t t - R u s t Quarry, H e r k i m e r County.
in Schoharie County. Amphilichas Acanthopyge
(Lobopyge)
contusa
(Hall
and
Clarke,
1888)
minganettsis
(Billings,
1865)
Lectotype G S C 1332a (Shaw, 1 9 6 8 ) , hypotypes N Y S M 1 2 2 1 9 - 3 4
Figure 5 . 1 C
Amphilichas
Types N Y S M 4 5 3 1 , 4 5 3 2
minganensis
is
reported
from
the
Middle
Ordo-
vician Chazy limestones and is the earliest lichid reported from
Hall and Clarke reported this trilobite f r o m the Upper Helder-
New York. F o r location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) . O n l y crani-
berg (Lower D e v o n i a n ) of eastern New York, Albany and O t s e g o
dia and pygidia are k n o w n f r o m m a t u r e specimens. T h i s is o n e of
Counties, and from O n o n d a g a ( M i d d l e D e v o n i a n ) f l o a t boulders
the few trilobites in New York from which significant i n f o r m a t i o n
in west-central
of growth stages is k n o w n f r o m silicified material. R a y m o n d
New York,
Ontario
County.
The
illustrated
specimen is f r o m Hall and Clarke ( 1 8 8 8 ) .
( 1 9 2 5 , p. 125) reported it to be also found in Q u e b e c and Virginia.
Amphilichas
Amphilichas
conifrons
(Ruedemann,
1916)
H o l o t y p e N Y S M 9 6 0 7 ; paratype N Y S M 9 6 0 8 ; s p e c i m e n s M C Z Amphilichas conifrons was described from
the
(Conrad,
1842)
T h e type is from Middle Ordovician Trenton age rocks in
1560, M C Z 1561 NYSM
trentonensis
Plesiotype M C Z 4 4 1 1
Middle
from a specimen
Ordovician
Trenton
in
collections
the
Pennsylvania. S p e c i m e n s f r o m New York that were referred by
of
Hall to this species are f r o m the lower Trenton at Middleville,
FIGURE 5 . 1 .
Lichids from the lower a n d lowest M i d d l e Devonian of New York. A. Ceratolichas dracon from the
O n o n d a g a Limestone in G e n e s e e County. The f i g u r e d c e p h a l o n is a reconstruction from Hall a n d Clarke (1888). B. Ceratolichas gryps from the O n o n d a g a Limestone at Schoharie, S c h o h a r i e County. The f i g u r e d c e p h a l o n is a reconstruction from Hall a n d Clarke (1888). C. Acanthopyge contusa from the O n o n d a g a Limestone in Ontario County. The figured g l a b e l l a is from Hall a n d Clarke (1888). D. Acanthopyge consanquinea from the New Scotland Limestone in Schoharie County. The f i g u r e d g l a b e l l a is from Clarke (1894). E. Echinolichas hispidus from the "Schoharie Grit," Schoharie, Schoharie County. The f i g u r e d p y g i d i u m is from Hall a n d Clarke (1888). F. Oinochoe bigsbyi from the shaly limestones of the lower H e l d e r b e r g G r o u p . D r a w i n g s 1 a n d 2 s h o w side a n d dorsal views of the glabella. D r a w i n g 3 s h o w s a partially r e c o n s t r u c t e d p y g i d i u m . The figures are from Hall ( 1 8 6 1 b ) .
126
THE
H e r k i m e r County. T h e whole s p e c i m e n figured by Hall ( 1 8 4 7 ) is
Dicranopeltis fragosa
from O h i o and probably a different species. A specimen in the
Holotype M C Z 100865
U S N M ( U S N M 6 3 0 3 ) i s from Pennsylvania.
(Phleger,
TRILOBITES
1937)
Lower Silurian Rochester Shale. T h i s trilobite is k n o w n only from a single c r a n i d i u m and may be Dicranopeltis nereus.
Arctinurus boltoni (Bigsby, 1 8 2 5 )
Plates 20 a n d 21
H o l o t y p e B M I t 1 5 6 9 0 ; hypotype N Y S M 9 6 3 1 ; s p e c i m e n s U S N M 4 9 9 5 4 3 , PRI 4 2 0 9 5 Arctinurus boltoni is f o u n d in the lower half of the Lower Silurian Rochester Shale in western New York. Arctinurus boltoni is o n e of the premier trilobites from New York. T h i s large, flat ovate trilobite has a b r o a d axis. T h e cephalon has a distinctive anterior tongue-shaped prow a n d h o o k - s h a p e d longitudinal furrows on the glabella. T h e pygidium is large and has three pairs of lobate spines. T h e large size ( 1 0 0 to 1 5 0 + m m ) and the pustulated exoskeleton make a striking display. T h e s e trilobites are very rare as whole, articulated s p e c i m e n s , and the types were only discovered during the digging of the Erie Canal in L o c k p o r t , Niagara County. Recently, large areas of the trilobite-rich layers of the Rochester Shale were uncovered in a shale q u a r r y near M i d d l e p o r t in Orleans C o u n t y , f r o m which sizable n u m b e r s of whole specim e n s have been taken. T h e s p e c i m e n i n Plate 2 0 , U S N M 4 9 9 4 5 3 , from the R o c h e s t e r Shale has e p i b i o n t s adhered to the surface, suggesting that the trilobite was m a t u r e and had not molted since the b r a c h i o p o d spat and o t h e r larvae lodged on the surface. T h e r e are two different b r a c h i o p o d s , b r y o z o a n s and Cornulites, species on
Dicranopeltis nereus (Hall,
1863)
Plates 22 a n d 23
Type A M N H 1 8 2 5 , s p e c i m e n PRI 4 9 6 2 3 Lower Silurian
Rochester Shale. Dicranopeltis nereus is found
in the lower R o c h e s t e r Shale in its western exposures (Tetreault 1 9 9 4 ) and at M i d d l e p o r t , Niagara County. T h e postaxial lobe of the pygidium has a rounded outline with a small median notch. T h e c r a n i d i u m of D. nereus has never been described. However, the c r a n i d i u m of D. fragosa described by Phleger (see above) could b e l o n g to D. nereus. T h e specimen in Plate 23 is from near M i d d l e p o r t and shows extensive healed damage to the left side, while the specimen in Plate 22 has healed damage to the right upper t h o r a x .
Echinolichas eriopsis
(Hall,
1863)
Plate 24
Syntypes N Y S M 4 5 3 7 t o 4 5 3 9 T h e illustrated s p e c i m e n s are from the O n o n d a g a Limestone and reported in Hall and Clarke ( 1 8 8 8 ) from the upper Helderberg at S c h o h a r i e , S c h o h a r i e County, and " d e c o m p o s e d chert b o u l d e r s " at C a n a n d a i g u a , O n t a r i o County.
the dorsal surface. T h e rhynchonellid b r a c h i o p o d apparently shows four growth stages, indicating a t i m e interval since the last
Echinolichas hispidus
m o l t . T h e trilobite in Plate 2 1 , PRI 4 2 0 9 5 , shows healed d a m a g e
Holotype N Y S M 4553
to the left side, possibly as a result of predator attack. T h r e e size
(Hall
and
Clarke,
1888)
T h e trilobite is reported from the Schoharie F o r m a t i o n at Clarksville, Albany C o u n t y , and O n o n d a g a L i m e s t o n e at LeRoy,
classes of b r a c h i o p o d s are evident on the surface.
Genesee County. Autoloxolichas?
inconsuetus
(Raymond,
1925)
Holotype M C Z 101164
Hemiarges paulianus
T h e h o l o t y p e , and only s p e c i m e n we are aware of, is a cranidium
Middle
Ordovician
Glens
Falls
1894)
Plate
25
Limestone
T h i s small lichid is from the Middle Ordovician, early Trenton
(basal T r e n t o n ) at the ( f o r m e r ) bridge at the falls of Flat Creek,
in New York. It has a wide geographic distribution west to M i n -
1.6 km (1
from
(Clarke,
Lectotype U S N M 4 2 4 3 a (Rudkin et al. 1994)
mile) south of Sprakers, M o n t g o m e r y County. No
c o m p a r i s o n s can be m a d e with o t h e r Trenton lichids. Ceratolichas dracon
(Hall a n d C l a r k e ,
1888)
Figure 5 . 1 A
Types N Y S M 4 5 3 4 t o 4 5 3 6 T h e illustrated s p e c i m e n is f r o m the O n o n d a g a L i m e s t o n e in Hall and Clarke ( 1 8 8 8 ) . Hall and Clarke reported the trilobite f r o m the upper Helderberg, Lower D e v o n i a n , at S c h o h a r i e , S c h o h a r i e County, and the M i d d l e Devonian at LeRoy, Genesee C o u n t y . Ceratolichasgryps (Hall
and Clarke,
1888)
Figure 5 . I B
Syntypes N Y S M 4 5 5 0 t o 4 5 5 2
nesota and n o r t h into C a n a d a . In New York cranidia and pygidia are c o m m o n l y f o u n d in the upper part of the Kings Falls Form a t i o n of the Trenton G r o u p , particularly in exposures just east of W a t e r t o w n in Lewis County. T h e trilobite in Plate 25 is from Trenton age quarries in O n t a r i o .
Lichid sp. Plate 26A Pygidium
of
an
unidentified
lichid
from
the
Middle
Devonian O n o n d a g a L i m e s t o n e in the Cheektawaga Quarry, Erie County. T h e specimen in Plate 26A differs from the known lichids in the O n o n d a g a .
T h e illustrated s p e c i m e n is f r o m the O n o n d a g a L i m e s t o n e and is in Hall and Clarke ( 1 8 8 8 ) . T h e trilobite is reported from
Oinochoe bigsbyi (Hall,
the upper Helderberg of Clarksville, Albany C o u n t y ; C h e r r y
Type A M N H 2 6 1 0 / 1
Valley, O t s e g o c o u n t y ; and " d e c o m p o s e d chert b o u l d e r s " at C a n a n d a i g u a , O n t a r i o County.
1859)
Figure 5 . I F
T h e illustrated specimen is from Hall and Clarke ( 1 8 8 8 ) and is in the New Scotland L i m e s t o n e .
ORDER
LICHIDA
Oinochoepustulosus
(Hall,
127 1859)
Plate 27
vature is greater anteriorly, but it is not strongly accentuated
Syntypes N Y S M 4 5 2 9 , 4 5 5 8 t o 4 5 6 4
anterodorsally. Viewed f r o m the dorsal side, the anterior part of
Oinochoe pustulosus is f o u n d in the New Scotland L i m e s t o n e
the m e d i a n lobe is less p r o m i n e n t . T h e furrow separating the
o f east-central New York. T h e c r a n i d i u m s h o w n , N Y S M E - 9 7 5 ,
third lateral lobes f r o m the c o m p o u n d anterior lateral ones
illustrates the source of the species n a m e pustulosus.
diverges m o r e to the front laterally. T h e specimen in Plate 30 is exceptional. T h e glabella of this s p e c i m e n is missing, probably as
Richterarges ptyonurus (Hall and Clarke, 1 8 8 8 ) Plate 28
a result of m o l t i n g . Note the Cornulites w o r m tubes on the right
Types N Y S M 4 5 5 5 t o 4 5 5 7
pygidial pleural surface. An e x a m p l e of the c r a n i d i u m , which is
Richterarges ptyonurus is reported by Hall a n d Clark from the "coralline limestone," now k n o w n as the Cobleskill F o r m a t i o n , in the area o f S c h o h a r i e , S c h o h a r i e County. T h e m e d i a n part o f the glabella, particularly in front of the level of the lateral glabellar
missing f r o m Plate 3 0 , is shown in Plate 3 1 . T h i s specimen is from Wayne County. Trochurus phlyctainoides
(Green,
1837)
furrows, S I , is flattened; the palpebral lobes are short and the
Trochurus phlyctainoides is a small o r n a t e lichid reported from
anterior branches of the facial sutures converge slightly forward.
the Rochester Shale. T h e species n a m e m e a n s having the form o f
T h e pygidium has a long axis and b r o a d e r postaxial ridge.
blisters or pustules, which is an apt description. T h e type is from
Richterarges trilobites are almost entirely restricted to n o r t h e r n
O h i o , and its actual presence in New York is q u e s t i o n a b l e . T h e
Laurentia. T h e only exception is R. ptyonurus.
reported material we are aware of is T. halli above.
Family Odontopleuridae
Terataspis grandis (Hall, 1 8 6 1 ) Plate 29
O d o n t o p l e u r i d s are f o u n d in New York f r o m the Middle
Holotype N Y S M 4 5 4 3 Type species. Onondaga
Terataspis grandis is f o u n d in both the lower
Limestone of western
New York, particularly the
former Fogelsanger Q u a r r y in Williamsville, Erie C o u n t y , and the upper Schoharie F o r m a t i o n of eastern New York. T h e large size and spiny nature of this trilobite make it o n e of the m o r e spectacular ones. A n u m b e r of models have been m a d e and are featured in Devonian reef d i o r a m a s , such as the o n e at the R o c h e s t e r Museum and Science ('enter, Rochester, New York. Only o n e specimen is known from New York; it is c o m p l e t e e n o u g h for a reasonable reconstruction. T h i s specimen is upside d o w n , and half, longitudinally, is missing. It is in the Buffalo M u s e u m of Natural History, Buffalo, New York. Plate 29 illustrates a genal spine from a large Terataspis s p e c i m e n . T h e An Eldredgeops specimen is included for scale. T h e drawing f r o m the Treatise shows where the genal spine appears on the exoskeleton. Using the relative scale of the drawing and the size of the genal spine, we can estimate an axial length, excluding pygidial spines, of a b o u t 38 cm ( 1 4 . 8 inches).
Trochurus bulbosa
(Phleger,
Ordovician to the base of the M i d d l e D e v o n i a n . W i t h the exception of the genus
Dicranurus, they are small
trilobites, easily
overlooked. T h e glabella tapers slightly forward, and the glabellar lobes are p r o m i n e n t . T h e genal spines are long, and short spines project d o w n , rakelike, from the lateral edges of the free cheeks. O f t e n there is o n e or m o r e occipital spines, which can be curved. T h e t h o r a c i c pleura end in long spines. T h e pygidium has a long pair of b o r d e r spines, with o n e or two pairs of s h o r t e r ones inside. Apianurus
narrawayi
(Raymond,
1910)
Topotype M C Z 7 6 9 7 Apianurus
narrawayi
is
an
uncommon
Middle
Ordovician
Chazy species. T h e type is lost, a n d Shaw ( 1 9 6 8 ) redescribed the species based on silicified material. B o t h A. narrawyi a n d Ceratocephala triacanthaspis f r o m the Chazy have two diverging o c c i p ital spines. Ceratocephala triacanthaspis is distinguished in that its c r a n i d i u m is covered with s h o r t spines. All the silicified material is f r o m very small s p e c i m e n s . For location i n f o r m a t i o n , see Shaw (1968).
1937)
Holotype M C Z 1555 Lower Silurian Clinton G r o u p , f o u n d in C l i n t o n drift (i.e., displaced rocks of Clinton age probably moved by glacial a c t i o n ) near Trenton Falls, Oneida County.
Ceratocara shawi ( C h a t t e r t o n , E d g e c o m b e , Vaccari, and Waisfeld, 1 9 9 7 ) Holotype N Y S M 15482 T h i s species is f r o m silicified material in the C r o w n Point Form a t i o n o f Valcour Island, C l i n t o n C o u n t y . Ramskold ( 1 9 9 1 ) f i r s t
Trochurus halli (Foerste, 1 9 1 7 ) Plates 30 and 31
noticed, in illustrations by Shaw ( 1 9 6 8 ) , that the remains of Cer-
Holotype A M N H 1826
atocera shawi were m i x e d
This trilobite from the Silurian Rochester Shale was originally designated
as
Trochurus phlyctainoides by
Hall
(1852).
theis.
Ceratocara
shawi
in with
differs
from
those of Ceratocephala C.
triacantheis
in
triacanlacking
Trochurus
sculpture on the glabella, o t h e r than the m a j o r pairs of spinose
halli species differs chiefly from T. phlyctainoides in the curvature
tubercles on the m e d i a n lobe, and in lacking sculpture on the
of the median lobe of the glabella, from front to rear. T h i s c u r -
lateral glabellar lobes.
128
THE
Ceratocephala
triacantheis
(Whittington
and
Evitt,
1954)
Meadowtownella trentonensis (Hall,
T h i s species is a Middle O r d o v i c i a n , middle Chazy trilobite
1847)
TRILOBITES
Plates 37 and 38
H o l o t y p e A M N H 8 5 3 / 2 , specimen M C Z 1 1 1 7 1 7
that Shaw ( 1 9 6 8 ) identified f r o m silicified material. For location
T h e type is from the M i d d l e Ordovician Trenton of Belleville,
i n f o r m a t i o n and illustrated s p e c i m e n s , see Shaw ( 1 9 6 8 ) . T h e type
O n t a r i o , and although it is not a good specimen, Ross ( 1 9 7 9 )
is from Virginia and is probably in the U S N M .
believed it to be a different trilobite from the Meadowtownella
Diacanthaspis parvula
been taken in reasonable n u m b e r s from the middle Trenton
specimen given this n a m e in New York. T h e New York species has (Walcott,
1877)
Plate 32
W a l c o t t - R u s t Quarry, H e r k i m e r C o u n t y , and is well represented
H o l o t y p e M C Z 4 3 7 2 , paratype M C Z 4 8 7 2 In New York D. parvula is primarily k n o w n f r o m the Middle Ordovician,
middle
Trenton
Walcott-Rust
Quarry,
in m a n y collections. Often the matrix with this trilobite contains
Herkimer
bryozoan and cystoid colonies. T h e trilobite is ornate, small, and
Diacanthaspis parvula
rarely over 2 . 5 c m (1 i n c h ) long. It makes an attractive specimen.
is found along with Meadowtownclla trentonensis. B o t h are small
Plates 37 and 38 show the dorsal and ventral exoskeletal a n a t o m y
trilobites with similar general shapes. T h e f o r m e r can be readily
of this trilobite.
County.
It is, however, fairly u n c o m m o n .
distinguished
from
M.
trentonensis because of its significantly
m o r e pustulose character and the presence of p r o m i n e n t pustules
Odontopleura
on the axis a n d pleural regions of the t h o r a c i c s e g m e n t s . It is
Hypotype N Y S M 9803
widely distributed geographically, being reported from Q u e b e c , Pennsylvania, and M i n n e s o t a .
ceralepta
(Anthony,
1838)
T h e type for this species is from the Upper Ordovician of O h i o . It has been reported from the Upper Ordovician W h e t s t o n e G u l f Shales near R o m e , O n e i d a County.
Dicranurus hamatus ( C o n r a d ,
1841)
Plate 33 Odontopleura sp.
Hypotypes N Y S M 4 1 9 0 t o 4 1 9 4 Lower D e v o n i a n New Scotland beds. T h i s trilobite is only
(Fisher,
1953)
Specimen B M S E16735
k n o w n from disarticulated parts in New York, but a close relative,
Lower Silurian M a p l e w o o d Shale, Rochester, M o n r o e County.
D. clegantus, f r o m O k l a h o m a is c o m p l e t e . Plate 3 3 , f r o m an O k l a -
Fisher illustrated a small articulated specimen and referred to it
h o m a s p e c i m e n , shows how D. hamata must have looked. T h e
as an Odontopleura species. Ludvigsen ( 1 9 7 9 b , p. 6 2 ) illustrated a
O k l a h o m a species is similar e n o u g h to be considered a subspecies
trilobite referred to as Leonaspis, which is n o w known as Exallaspis
by C a m p b e l l ( 1 9 7 7 ) . T h e curved hornlike occipital spines are very
( R a m s k o l d and C h a t t e r t o n 1 9 9 1 ) , and reported from the Cataract
distinctive.
by a variety of
G r o u p of C a n a d a . T h e M a p l e w o o d Shale is younger than the
epibionts such as bryozoa, b r a c h i o p o d s , c r i n o i d s , corals, and
Cataract G r o u p (Brett et al. 1 9 9 5 ) . T h i s trilobite may be Exallaspis,
w o r m tubes, as well as b o r i n g s referred to as endoliths. T h e r e
but m o r e material is needed to make identification possible.
T h e spines
are often
encrusted
is evidence that these encrusters were on the trilobite while it was alive ( K l o c 1 9 9 2 , 1 9 9 3 , 1 9 9 7 ) .
Primaspis (Miraspis?) crosota ( L o c k e ,
1 8 3 8 ) Plate 39
Hypotypes N Y S M 9 8 0 4 t o 9 8 0 6 , U S N M 3 4 6 1 7 Kettneraspis callicera (Hall and Clarke, 1 8 8 8 ) Plate 34
Primaspis crosota is an O h i o species from the Upper O r d o v i -
Hypotypes N Y S M 4 1 8 6 t o 4 1 8 9 Upper Clarksville,
Lower/lower Albany
Canandaigua,
Middle
County,
Ontario
cian. It has been reported from the Middle Ordovician Trenton Devonian,
and
County.
Schoharie
Onondaga
Note
in
Grit,
Limestone
Plate
34
how
age, C a n a j o h a r i e and Dolgeville Shales, M o n t g o m e r y County, to
at
the Upper Ordovician Lorraine G r o u p shales at Totman G u l f in
the
Jefferson County. Plate 39 is U S N M 2 3 6 0 0 from the Upper
genal spine ends with a " h o o k " shape.
Ordovician Frankfort F o r m a t i o n in O n e i d a County.
Kettneraspis tuberculata ( C o n r a d ,
5.5 ORDER PHACOPIDA
1 8 4 0 ) P l a t e 35
Hypotypes N Y S M 1 0 7 0 4 , 1 0 7 0 5 , 4 1 9 6 t o 4 2 0 0
This
post-Cambrian
order
contains
many
of
the
more
Lower Devonian New S c o t l a n d beds. Disarticulated parts of
c o m m o n trilobites from the Ordovician through the Devonian o f
this species are c o m m o n in s o m e of the limestones and shales of
New York. T h e suborder Phacopina contains the only trilobite
the New Scotland F o r m a t i o n . Articulated s p e c i m e n s such as the
families with schizochroal eyes.
o n e in Plate 35 are rare. Note the a b u n d a n c e of p r o m i n e n t t u b e r cles on the exoskeleton, which p r o m p t e d the n a m e .
Family Acastidae
Kettneraspis sp. Plate 36
c o m b e ( 1 9 9 3 ) and includes Greenops and related species that are
T h e family Acastidae ( D e l o 1934) was resurrected by EdgeT h i s s p e c i m e n has been collected f r o m the New Scotland
popular with trilobite collectors in New York. In New York the
L i m e s t o n e . It is distinguished from k n o w n material by the very
family is primarily restricted to the M i d d l e Devonian and then
long cephalic b o r d e r spines.
mostly to the H a m i l t o n G r o u p . T h e s e trilobites have schizochroal
ORDER
PHACOPIDA
129
eyes, which, because they are raised above the plane of the
greater n u m b e r of axial rings in the pygidium c o m p a r e d to
cephalon, are often damaged or lost during the collecting process.
Greenops species. Because the h o l o t y p e is lost and no neotype
T h e subfamily Astropyginae, which includes Greenops, currently
from Pennsylvania has been designated, the presence of this trilo-
is under revision because of the observation that m a n y m o r e
bite is u n k n o w n in New York. M o s t s p e c i m e n s in New York pre-
species apparently are represented in the s p e c i m e n s in m u s e u m s
viously assigned to G. calliteles have been reassigned to other
and private collections than are currently recognized. A revision
species ( L i e b e r m a n and Kloc 1 9 9 7 ) .
(Lieberman and Kloc 1997) divides the f o r m s k n o w n in New York as Greenops boothi and G. calliteles into new genera and species.
Bellacartwrightia jennyae
Tables 5.3 and 5.4 give descriptive i n f o r m a t i o n not included
Plates 4 2 a n d 4 3
below.
Holotype A M N H
(Lieberman
45312,
and
Kloc,
paratype A M N H
1997)
4 5 3 1 0 , specimen
NYSM 4235 Type species. T h i s trilobite is f o u n d in the Centerfield L i m e -
Subfamily Asteropyginae Plate 40
s t o n e M e m b e r o f the H a m i l t o n G r o u p i n Livingston County. This
Specimen in private collection ( G . K l o c ) T h e specimen is from the Tully L i m e s t o n e in Groves Creek o f f
type species is characterized by the s m o o t h pygidial lappets
Cayuga Lake. It is characterized by b r o a d e n i n g of the anterior
a n d their triangular cross section. Plate 42 is the paratype. T h e
border in front of the glabella, S2 meeting the glabellar furrow,
cluster in
prominently pustulose a cephalon, and rounded pleural s e g m e n t s
and
on the pygidium.
by Hall a n d Clarke ( 1 8 8 8 , Plate 2 4 . 1 5 ) and is from Centerfield in
two
Plate 43 of three
(one hidden)
Harpidella craspedota
Bellacartwrightia jennyae s p e c i m e n s was
first
illustrated
O n t a r i o County. T h e smaller B. jcnnyi has small pustules on the Bellacartwrightia
calderonae
(Lieberman
and
t h o r a c i c pleural lobes and axis that are not f o u n d on the larger
Kloc,
specimen.
1997) Plate 41 Holotype A M N H 4 5 2 7 3 W i n d o m M e m b e r , Hamilton G r o u p , O n t a r i o County. T h e
Bellacartwrightia phyllocaudata
cephalon has a broad flat anterior m a r g i n , axial nodes on the
1 9 9 7 ) Plate 4 4
thorax, and pustules on the lappets.
Holotype A M N H 4 5 2 3 0
(Lieberman
and
Kloc,
W i n d o m and D e e p Run M e m b e r s , H a m i l t o n G r o u p , LivBellacartwrightia
calliteles
(Green,
1837)
ingston C o u n t y . T h e s p e c i m e n in Plate 44 is the h o l o t y p e . T h e pygidial lappets on this species are pustulose, flat, and sharply
Holotype lost It is evident from Green's ( 1 8 3 7 a ) description that Cryphaeus calliteles
would
be
assigned
to
Bellacartwrightia,
owing
to
the
pointed with a thin sharp extremity, and the axial lappet is b r o a d e r at the base than the o t h e r lappets.
Table 5.3. Defining features of the New York asteropygins Bellacartwrightia
Greenops
Kennacryphaeus
Moderate to broad cephalic border
Narrow cephalic border
Eye: maximum of 8 to 10 lenses in a dorsoventral file Posterior border furrow is deflected backward on the genal spine
Eye: maximum of 6 lenses in a dorsoventral file Posterior border furrow is straight. ending halfway across the genal spines
Cranidial anterior border lengthened slightly medially, developed as a narrow lip Eye: maximum of 8 lenses in a dorsoventral file Posterior border furrow is deflected backward on the genal spine
Thorax
Axial spines or nodes on thoracic segments
No axial thoracic spines, sometimes nodes
Thoracic axial spines
Pygidium
14 to 16 pygidial axial rings Tops of pygidial pleural segments rounded in anteroposterior view Posterior portion of pygidial axis prominently excavated
11 pygidial axial rings Tops of pygidial segments flat in anteroposterior view Posterior portion of pygidial axis faintly excavated
Posterior portions of pygidial pleural segments elevated above anterior portion
Interior and posterior portions of pygidial pleural segments of equal elevation
14 pygidial axial rings Tops of pygidial pleural segments rounded Pygidial pleural field flanking posterior portion of pygidial axis faintly excavated Interior and posterior portions of pygidial pleural segments of equal elevation
Cephalon
Table 5 . 4 .
Horizon
Features of the genera Bellacartwrightia and Greenops
B. jennae
B. whiteleyi
B. calderonae
B.
Hamilton,
Hamilton, Wanakah
Hamilton, Windom
Hamilton, D e e p
Axial furrow narrow a n d shallow, nearly straight anterior of SO, diverging forward at about 25 degrees
B. pleione
G. boothi
G. barberi
G. grabaui
Onondaga
Frame Group in Pennsylvania
Hamilton.
Hamilton,
U. Wanakah, Windom Faint or absent
Centerfield, Ledyard, Wanakah Faint or absent
Run, Windom
Centerfield Cephalon
phyllocaudata
Axial furrow narrow a n d shallow, nearly straight anterior of S 1 . diverging forward at about 35 degrees
Axial furrow narrow and shallow, nearly straight anterior of S 1 , diverging forward at about 35 degrees
Axial furrow narrow and shallow, diverging more strongly anterior of S 1 , diverging forward at about 45 degrees
Unknown
Prominent axial tubercle on LO
axial tubercle on LO
axial tubercle on LO
Numerous and large circular perforations on glabellar and palpebral lobes Thorax
Has circular perforations Axial spines
Pygidium
Pygidial lappets are triangular in cross section 14 pygidial axial rings Pygidial lappets lack, or have very fine, prosopon of small granules
Has circular perforations Axial spines
No circular perforations Axial nodes
Pygidial lappets are oval in cross section 14 pygidial axial
Pygidial lappets are oval in cross section 14 pygidial axial
rings Pygidial lappets have prosopon of
rings Pygidial lappets have prosopon of
No circular
Unknown
perforations Axial spines
Pygidial lappets are flat 15 to 16 pygidial axial rings Pygidial lappets have prosopon of small granules
small granules
small granules
Terminal pygidial lappet narrow
Terminal pygidial lappet narrow
Terminal pygidial lappet narrow
Terminal pygidial
Circular perforations in the pleural area
Circular perforations in the pleural area
No circular perforations in the pleural area
No circular perforations in the pleural area
lappet broad
Pygidial lappets are oval in cross section 15 pygidial axial
Two transverse rows of circular perforations on anterior b a n d of pleural segments
One transverse row of circular perforations on anterior b a n d of pleural segments
One transverse row of circular perforations on anterior b a n d of pleural segments
No axial nodes or spines
No axial nodes or spines
No axial N o d e s or spines
Tips of lappets developed as blunt triangles
Tips of lappets
Tips of lappets d e v e l o p e d as blunt triangles
Terminal pygidial lappet broad anteriorly, subrectangular, convex posteriorly Medial margins of
Terminal pygidial lappet developed as a narrow, sharp triangle
Terminal pygidial lappet subrectangular
Medial margins of lappets curved, lateral margins curved
Medial margins of lappets straight, lateral margins curved
pointed
rings Pygidial lappets have prosopon of small granules Terminal pygidial lappet narrow
Circular perforations in the pleural area
lappets curved, lateral margins curved
ORDER
PHACOPIDA
Bellacartwrightia pleione
131
(Hall
and
Clarke,
1888)
H a m i l t o n , indicating their capability to live in poorly oxygenated
Holotype A M N H 4 2 4 8
waters. In the Ledyard pyrite beds, Genesee County, o n e finds
This species is found from the Middle Devonian O n o n d a g a
whole,
pyritized
G.
"boothi"
specimens.
Greenops
"boothi"
is
Limestone through the Tully F o r m a t i o n in n u m e r o u s localities in
reported f r o m the U p p e r D e v o n i a n beds of south-central New
western New York. T h e holotype is f r o m Kentucky.
York, T o m p k i n s C o u n t y , b u t little work has been d o n e on these o c c u r r e n c e s . In the N Y S M there is an exfoliated pygidium from
Bellacartwrightia
whiteleyi
(Lieberman
and
Kloc,
an
1997)
acastid,
possibly
Greenops,
from
the
Upper
Devonian
Plates 45 and 145
Rhinestreet or Cashagua Shale, Erie C o u n t y . T h e Pennsylvania
Holotype A M N H 4 5 3 1 3 , paratype A M N H 4 5 3 1 4
trilobite shown in Plate 51 ( t h e n e o t y p e f r o m the type locality) is
Wanakah M e m b e r , H a m i l t o n G r o u p , Genesee County. Plate
included for c o m p a r i s o n . P r i o r to the paper by L i e b e r m a n and
45 illustrates the paratype. Bellacartwrightia whiteleyi has pygidial
Kloc ( 1 9 9 7 ) , all the New York acastids were l u m p e d under G.
lappets, which are covered with small pustules and are semicir-
boothi or G. calliteles. Greenops boothi has a d o u b l e row of perfo-
cular in cross section. T h e axial lappet is n a r r o w and sharply
rations on each of the t h o r a c i c pleural segments and a broad axial
pointed.
pygidial lappet with a triangular t e r m i n a t i o n .
Bellacartwrightia
sp.
Plate
46
Greenops grabaui ( L i e b e r m a n a n d K l o c , 1 9 9 7 ) Plates 5 2 , 5 3 ,
USNM 89959
and 5 4
This undescribed species from the Tully L i m e s t o n e is c h a r a c terized by the very broad anterior b o r d e r and the triangular pygidium.
Holotype B M S E25857 Centerfield, Ledyard, and W a n a k a h M e m b e r s o f the H a m i l t o n G r o u p in Genesee C o u n t y . T h e pygidial lappets of G. grabaui are short and b r o a d , with the a n t e r i o r edge curved posteriorly and
Bellacartwrightia? sp.
Plates 47
and
48
the posterior edge straight. T h e terminal lappet is short, broad,
T h e specimen in Plate 47 c a n n o t be identified by the internal exoskeletal
anatomy.
It
was
prepared
to
s h o w the
internal
and subrectangular. Plate 53 illustrates a meraspid (degree 10) of this c o m m o n
Greenops species.
exoskeletal characteristics. T h e illustrated s p e c i m e n in Plate 48 is undescribed but has s o m e characteristics similar to B. whiteleyi.
Greenops sp. Plates 55 a n d 56
It differs in the broad shape of the pygidium and wider spacing
U n d e t e r m i n e d species f r o m the upper H a m i l t o n .
between the lappets. Kennacryphaeus Asteropyginae aff. Greenops Plate 49
harrisae
(Lieberman
and
Kloc,
1997)
Holotype A M N H 4 5 2 9 8
T h e specimen in Plate 49 is a small trilobite f r o m the P o m p e y M e m b e r in central New York.
Mottville M e m b e r and Stafford L i m e s t o n e , H a m i l t o n G r o u p , Onondaga County.
Greenops barberi ( L i e b e r m a n a n d K l o c , 1 9 9 7 )
Family Calymenidae
Plate 50
Holotype PRI 4 1 9 4 7 , paratype A M N H 4 5 2 7 7
T h e family C a l y m e n i d a e arose in the Early O r d o v i c i a n in
Upper Wanakah and W i n d o m M e m b e r s , H a m i l t o n G r o u p ,
Europe and migrated to N o r t h A m e r i c a during the early Middle
Erie County. T h e pygidial lappets on G. barberi are relatively long
O r d o v i c i a n . In general, the c e p h a l o n is semicircular, usually with
and narrow, and both the anterior and posterior edges are curved
no genal spines. T h e glabella is p r o m i n e n t l y convex and narrows
posteriorly. T h e axial lappet is narrow, relatively long, and trian-
anteriorly, yielding an o u t l i n e that can range f r o m bell shaped to
gular. Plate 50 illustrates the paratype.
parabolic. T h e r e is usually a distinct preglabellar area, or "lip," the shape of which has s o m e species significance. T h e r e are three
Greenops boothi ( G r e e n ,
1837)
Plate 51
or four distinctive lateral glabellar lobes. T h e posterior pair of
Holotype lost, neotype Y P M 3 5 8 0 7 L i e b e r m a n and Kloc, 1997
lobes, L I , are the largest. T h e pygidium is s o m e w h a t triangular
Type species. T h e long lost type for G. boothi is f r o m the
to semicircular with a s m o o t h edge. T h e N o r t h A m e r i c a n caly-
Middle Devonian F r a m e M e m b e r o f the H a m i l t o n Shales o f
menids have 13 t h o r a c i c s e g m e n t s . T h e exoskeleton of the caly-
central Pennsylvania. In describing the New York species, Hall
menids is robust, and clearly recognizable pieces are often found
accepted all asteropygins with short, r o u n d e d pleural lappets as
in fossil lag deposits. Because of this, and their presence in a wide
G. boothi and all with long, spinelike lappets as G.
callitelcs.
variety
of p a l e o e n v i r o n m e n t s ,
Greenops "boothi" is a c o m m o n fossil of the H a m i l t o n Shales, pri-
species
the
marily as whole cephalon and pygidial exuviae. W h o l e s p e c i m e n s
O r d o v i c i a n trilobites e n c o u n t e r e d in the field. E d g e c o m b e and
are infrequently e n c o u n t e r e d . Along with Eldredgeops rana,
Adrain ( 1 9 9 5 ) reviewed the Silurian calymenids of the United
G.
"boothi" is o n e of the trilobites f o u n d in the dark shales of the
States.
distinction
calymenids
o f being
the
most
share
with
common
Isotelus Middle
132
THE
Calymene camerata
(Conrad,
1842)
Plate
57
Calymene singularis (Howell a n d S a n f o r d ,
Hypotypes N Y S M 4 1 6 3 t o 4 1 6 5
1947)
TRILOBITES Plate 61
Holotype U S N M 4 8 8 1 3 9 Upper
T h e type for this c a l y m e n i d is from the Upper Silurian " O a k
Silurian Cobleskill L i m e s t o n e in the S c h o h a r i e Valley, S c h o h a r i e
O r c h a r d M e m b e r " of the L o c k p o r t G r o u p in M o n r o e County. It
County. T h i s trilobite is characterized by the deep furrow in front
was originally described as Cheirurus singularis. Holloway ( 1 9 8 0 )
of the glabella. T h i s feature is interpreted to indicate that the
recognized it as a c a l y m e n i d .
Calymene camerata
is
reported
from
the top
of the
preglabellar area is steeply u p t u r n e d , similar to the familiar Flexicalymene
Calymene?
meeki.
conradi
This
(Emmons,
1855)
senaria
for
the
Calymene
species
is
from
the
eastern
eyes, a m o r e tapered anterior p o r t i o n of the glabella, and the
T h i s species was described by E m m o n s to replace the use Flexicalymene
P l a t e 62
unidentified
Rochester Shale in Wayne County. It is characterized by smaller
Specimen U S N M 78402 of
Calymene sp.
Upper
Ordovician
Lorraine
o r n a m e n t a t i o n on the c e p h a l o n . C a l y m e n i d sp. P l a t e 6 3
Shale calymenids of New York. It was described as follows: " S m a l l ,
T h e r e are at least two calymenids of the Upper Ordovician
wide across the cheeks, cheek angles o b t u s e or r o u n d e d ; poste-
f o u n d in New York. T h e y have been referred to as Flexicalymene
rior
lobes
of the
glabella
comparatively
large
and
globu-
lar; t h o r a c i c lobes very convex, with a row of tubercles in the furrow or between the axis and the lateral lobes." It was f o u n d in the L o r r a i n e Shales f r o m an i n d e t e r m i n a t e location in central New York.
meeki a n d F. granulosa.
C a l y m e n i d sp. Specimen O S U 22763, 4 Leutze
Calymene niagarensis ( H a l l ,
1843)
(1961)
illustrated
Plates 58 a n d 59
although it has been reported f r o m rocks above and below. Calymene niagarensis has a bell-shaped glabella. T h e anterior b o r d e r
( E d g e c o m b e a n d Adrain 1 9 9 5 ) . Diacalymene
Lectotype S D S N H 8 6 8
best
known
defined
of the
axial
rings.
fine granules. Lower
Silurian
The
Calymene
exoskeleton niagarensis is
calymenids
the
F o r m a t i o n s , there are c a l y m e n i d species that may be the same
to the cephalon is s h o r t and strongly convex. T h e preglabel-
dense,
from
cific identification. In M a r y l a n d in the Will Creek and Toholoway
lar area is a b o u t 1 0 % of the cranidial length. T h e pygidium has completely
collected
O n o n d a g a C o u n t y . T h e specimens are too f r a g m e n t a r y for spe-
T h i s species is f r o m the Lower Silurian R o c h e s t e r Shale,
covered with
specimens
Camarotoechia zone in the Upper Silurian Syracuse F o r m a t i o n in
Holotype A M N H 31063
seven
M o r e work needs to be d o n e on these
specimens
because
is the
rostrata
T h e type from
the
(Vogdes,
is f r o m
1879)
Georgia.
Diacalymene rostrata
Lower Silurian, lower Clinton
in
is
reported
Oneida County
the
(Gillette 1 9 4 7 ) . Vogdes wrote: " D i s t i n c t projecting process in
quarrying activities in the R o c h e s t e r Shale near M i d d l e p o r t in
front of the glabella. T h e facial lines cut the anterior b o r d e r at the
Orleans C o u n t y have uncovered large n u m b e r s . T h e original
apex, giving the frontal limb a triangular f o r m ; at their j u n c t u r e
material was u n d o u b t e d l y f r o m the digging of the Erie Canal
the marginal b o r d e r is raised and forms a triangular process
in L o c k p o r t , Erie C o u n t y . T h e r e are at least three calymenids in
which s u p p o r t s the projection." There is no b a s i s to d i s t i n g u i s h
the
most
New York material as different from that f r o m Georgia. T h e
c o m m o n . Plate 58 shows an individual of the species. Plate 59
a n t e r i o r b o r d e r of the cephalon is moderately long and c o m e s
shows a cluster of C.
niagarensis s p e c i m e n s f r o m M i d d l e p o r t ,
to a p o i n t . T h e pygidial axis has eight or nine distinct interring
o n c e again d e m o n s t r a t i n g the gregarious nature of s o m e trilo-
furrows and a long terminal piece. See E d g e c o m b e and Adrain
bites. Clusters of this kind have been described as m o l t i n g or
( 1 9 9 5 ) for a recent description of the species.
Rochester
Shale,
and
C.
niagarensis
is
easily
the
breeding assemblages.
Calymene platys
(Green,
Diacalymene 1832)
Plate 60
Plastotype N Y S M 4 1 6 8 Calymene platys represents the latest o c c u r r e n c e of calymenids in New York. It is f o u n d in the top of the Lower Devonian S c h o h a r i e Grit and the base of the O n o n d a g a in S c h o h a r i e , Albany and Erie C o u n t i e s . T h e cast of Green's type in the U S N M is pustulose. T h e s p e c i m e n shown in Plate 6 0 , from the O n o n d a g a
vogdesi
(Foerste,
1887)
Holotype U S N M 84790a T h i s Silurian trilobite from O h i o has been reported from the Lower Silurian Rochester Shale of New York. T h i s o c c u r r e n c e c a n n o t be verified. See E d g e c o m b e and Adrain ( 1 9 9 5 ) for m o r e information. Diacalymene sp. Two
Plates 6 4 , 65
undescribed Diacalymene species are k n o w n
from
the
of O n t a r i o , has a s m o o t h surface; however, this may be due to
R o c h e s t e r Shale in M o n r o e and Wayne C o u n t i e s . T h e o n e illus-
weathering.
trated in Plate 64 has a triangular anterior cephalic margin. T h e
ORDER
133
PHACOPIDA
other, in Plate 6 5 , has a m o r e r o u n d e d margin. T h e s e will be
Trenton G r o u p , H e r k i m e r County. T h i s trilobite, part of the revi-
described as different species.
sion m e n t i o n e d above, has a very pustulose exoskeleton and short genal spine on the fixed cheeks. T h e facial sutures are proparian.
Flexicalymene granulosa
(Foerste,
1909)
T h i s species has been observed t h r o u g h o u t the Rust Limestone in
Hypotype N Y S M 9 6 4 9
the Trenton Falls area.
R u e d e m a n n ( 1 9 2 6 ) identified pustulose calymenids f o u n d in the Upper Ordovician W h e t s t o n e G u l f Shale in Jefferson C o u n t y
Gravicalymene
as
and 72
Calymene
granulosa.
Foerste
(1924)
described
C.
granulosa
as follows: "size, relatively small. A n t e r i o r b o r d e r of the c e p h alon less abruptly elevated than in C. meeki. Surface covered by n u m e r o u s granules, larger and m o r e c o n s p i c u o u s than those in the latter species." Hughes and C o o p e r ( 1 9 9 9 ) illustrated Flexicalymene cf. F. granulosa from Kentucky. Flexicalymene meeki ( F o e r s t e ,
1910)
Flexicalymene
meeki
as
follows:
"glabella
relatively short, with a tendency towards t r u n c a t i o n anteriorly. Anterior border of cephalon turned up abruptly and separated from the front of the glabella by a narrow groove. Genal angles with a short, acute, pointed extremity. Ribs of the pygidium with only a very faint trace of an impressed zone along their m e d i a n line." T h e
USNM
specimen
is
from
1926)
Plates
71
Holotype N Y S M 9650 T h i s M i d d l e O r d o v i c i a n trilobite, first figured by R u e d e m a n n as Flexicalymene senaria, was given subspecies rank in
1926. Ross
( 1 9 6 7 ) pointed o u t in s o m e New York calymenids that not only senaria being parabolic) b u t also the a n t e r i o r b o r d e r was thick-
Plate 66
USNM 23627 described
(Ruedemann,
was the glabella bell shaped in outline (vs. the glabella in F.
Holotype U S N M 7 8 8 2 2 ( O h i o ) , hypotype N Y S M 9 6 5 5 , specimen Foerste
magnotuberculata
the
U p p e r Ordovician
"Pulaski Drift" from north o f Utica, O n e i d a County. Similar material is in the N Y S M and the M C Z . T h e s p e c i m e n in Plate 66 is from C i n c i n n a t i , O h i o , the type area for the species. Flexicalymene senaria ( C o n r a d , 1 8 4 1 ) Plates 6 7 , 6 8 , 6 9 , a n d 70 Neotype A M N H 2 9 4 7 4 (Ross 1967) Flexicalymene senaria was o n e of the earlier New York trilobites recognized as being different f r o m its European c a l y m e n i d counterparts. It is f o u n d nearly everywhere that the M i d d l e Ordovician limestones are exposed in New York. T h e n e o t y p e , Plate 67, is from Middleville, H e r k i m e r C o u n t y , and is probably
ened and
rolled c o m p a r e d
to the standards for Flexicalymene.
Ross did n o t , however, m e n t i o n R u e d e m a n n ' s subspecies, and the assignment as Gravicalymene is based on Ross's general observations for the species and o u r e x a m i n a t i o n of s p e c i m e n s . T h e genal angle is very r o u n d e d . T h e facial suture is g o n a t o p a r i a n . Ruedemann's s p e c i m e n s
came
from
the T r e n t o n
age, C a n a j o h a r i e
Shales, and we have observed the s a m e trilobite in Dolgeville-like facies within the Sugar River F o r m a t i o n of the T r e n t o n . Plates 71 and 72 illustrate the dorsal and ventral exoskeletal surfaces. Liocalymene clintoni
(Vanuxem,
1842)
Plate
73
Hypotype M C Z 104689 T h e location of the original type is u n k n o w n . Liocalymene clintoni is listed f r o m the Lower Silurian, lower and middle C l i n t o n G r o u p in O n e i d a C o u n t y ( D a l e 1 9 5 3 ) . T h e trilobite has a bell-shaped glabella with very large first glabellar lobes ( L I ) . T h e glabellar lobes are m u c h less inflated than those in Calymene species. It is easily distinguished from o t h e r calymenids in that the pleural region of the pygidium is s m o o t h , without pleural grooves. See R a y m o n d ( 1 9 1 6 ) and W h i t t i n g t o n ( 1 9 7 1 a ) .
from the lower Trenton. T h e illustrated s p e c i m e n in Plate 68 is from the lower Poland L i m e s t o n e from Trenton Falls, H e r k i m e r
Liocalymene
County. T h e trilobite in Plate 69 is from the W a l c o t t - R u s t Q u a r r y
Lectotype U S N M 1 6 4 0 6 4 ( E d g e c o m b e and Adrain 1 9 9 5 )
in the Rust F o r m a t i o n of the Trenton G r o u p ; Ross ( 1 9 6 7 ) suggested this was a separate species owing to its unusually pustulose appearance. T h e specimen in Plate 70 is f r o m the u p p e r m o s t Trenton, the Hillier M e m b e r , and is less pustulose. It is interesting, however, that in spite of the n u m b e r of trilobite workers splitting o f f new species from early New York discoveries, it was not
cresapensis
(Prouty,
1923)
Liocalymene cresapensis was originally described
f r o m the Sil-
urian of M a r y l a n d . Dale ( 1 9 5 3 ) reported the trilobite from the Lower Silurian, upper C l i n t o n G r o u p shale o f O n e i d a County.
Family Cheiruridae C h e i r u r i d s are c o m m o n trilobites o f the Middle Ordovician
recognized a " s u b s p e c i e s " of F.
of New York. T h e y are also m o r e rarely f o u n d in the Silurian.
senaria. In 1967 Ross similarly pointed out that there are at least
Generally, the glabella expands forward and there are genal
four different trilobites in New York called F. senaria. Revision of
spines. T h e t h o r a c i c pleurae have short spines, although s o m e -
this group is presently in progress.
times these are b l u n t . T h e r e is an o b l i q u e furrow on the thoracic
until
1926 that R u e d e m a n n
pleura next to the axis. T h e pygidium is small and usually with Flexicalymene sp.
(Ross,
marginal
1967)
Ross identified the specimen from the W a l c o t t - R u s t Q u a r r y in
the
Rust
Limestone
spines.
Pribyl, Vanek,
and
Pek
(1985)
extensively
reviewed and modified the cheirurids in a work that is not readily
Specimen N Y S M 17004 Member
of the
Middle
Ordovician
available in most libraries. T h e genera referred to in the following are f r o m their paper.
134
THE
Acanthoparypha
trentonensis
Cerauropeltis
Holotype N Y S M 4766
(Raymond,
1916)
Plate
84C-E
H o l o t y p e N Y S M 9 6 8 9 , hypotype M C Z 101171
R a y m o n d ( 1 9 2 5 ) initially identified A.
trentonensis as Kawina,
with two cranidia from the M i d d l e O r d o v i c i a n material in the Walcott collection
ruedemanni
TRILOBITES
Type species.
Cerauropeltis
ruedemanni from
the base of the
Middle O r d o v i c i a n , upper Chazy resembles C. plcurexanthemus
( M C Z ) , probably from Herkimer County.
with the following differences. A crease j o i n s the proximal ends
R a y m o n d ( 1 9 2 5 , p. 145) additionally listed the species f r o m the
of the glabellar furrows, giving the glabella a trilobed appearance,
Black River of New Jersey.
and the second pleural spines on the pygidium are elongated. All of the k n o w n material is f r o m a single location (Shaw 1 9 6 8 ) . T h e
Acanthoparypha?
sp.
(Shaw,
fixed cheek has a wrinkled look. S p e c i m e n s are huge. O n e in the
1968)
M C Z has a glabella 3.7 cm long.
Specimens N Y S M 12435 to 12438 This Middle O r d o v i c i a n Chazy trilobite is only k n o w n f r o m a few pieces. For location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
Ceraurus
montyensis
(Evitt,
1953)
Holotype U S N M 116693a Ceraurinella
(Ceraurinella)
latipyga
(Shaw,
1968)
Plate
This
86C
Middle
Ordovician
Trenton
cheirurid
from
north-
eastern New York near the town of Chazy, Clinton County, is
Holotype N Y S M 12442 A Middle O r d o v i c i a n Chazy trilobite that was first described
very similar to C. pletirexanthemus.
T h e silicified material Evitt
studied has a less elevated eye on the free cheek, and the pygid-
by Shaw. For location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
ium appears to be m o r e scalloped or dentated than that of C. Ceraurinella
(Arcticeraurinella)
scofieldi
(Clarke,
plcurexanthemus.
1894)
Plate 7 4 Hypotype M C Z 100814
Ceraurus pleurexanthemus
T h e M C Z s p e c i m e n i s f r o m the M i d d l e O r d o v i c i a n Black
(Green,
1832)
Plates 7 6 , 7 7 , and 78
Holotype N Y S M 4 2 0 3 ; specimens M C Z 111708, M C Z 111715
River L i m e s t o n e near Poland, H e r k i m e r C o u n t y , and is part of
Type
species.
Ceraurus
pleurexanthemus
is
a
common
and
the Walcott collection. T h i s trilobite is also reported f r o m the
widely distributed trilobite of Middle Ordovician Trenton age
C h a u m o n t L i m e s t o n e in the W a t e r t o w n Town Q u a r r y , W a t e r -
rocks in central New York. T h e distinctive cephalon with its long
t o w n , Lewis C o u n t y . T h e original described material is from the
divergent genal spines and the two long marginal pygidial spines
Midwest; see D e M o t t ( 1 9 8 7 ) .
m a k e it easy to identify. Articulated specimens are u n c o m m o n in m o s t exposures, as it was not as robust as Isotelus gigas or Flexi-
Ceraurinus
marginatus
(Barton,
1913)
Plate
calymene senaria f o u n d in the s a m e rocks. T h e exception is the
75
W a l c o t t - R u s t Q u a r r y , H e r k i m e r County, where large n u m b e r s of
Holotype M C Z 100813 T h e h o l o t y p e is f r o m the Hillier M e m b e r ,
w h o l e , articulated s p e c i m e n s of all sizes are found in and on a
Middle O r d o v i c i a n Trenton G r o u p , Jefferson C o u n t y . T h i s is a
single layer. T h i s s a m e layer yielded specimens with appendages,
reasonably c o m m o n trilobite f r o m the C o b o u r g o f southern
which Walcott used in his first description of trilobite ap-
O n t a r i o but rarely reported in New York. T h e r e are u n n u m b e r e d
pendages. Plate 76 provides an excellent example of the species.
s p e c i m e n s in the U S N M , three small pieces a n d a very large
Plate 77 shows the ventral exoskeletal anatomy. T h e a p o d e m e s of
Type species.
glabella, 2.3 cm long. T h e y are f r o m 3 m ( 1 0 feet) b e n e a t h the
Plate 77 are clublike at the ends. T h e specimen in Plate 78 shows
top o f the M i d d l e O r d o v i c i a n Trenton o n the N o r t h Fork o f
a ferriginous trace of the gut from the midpoint of the t h o r a x to
Sandy Creek,
the end of the pygidium.
7.2 k m
(4.5
miles)
south
of Adams,
Jefferson
County. T h e s p e c i m e n in Plate 75 is f r o m the T r e n t o n age rocks of Ontario.
Ceraurus? sp. Plates 79 a n d 80 T h e s p e c i m e n shown in Plate 79 is from a flooding-surface
Ceraurinus
sp.
lag
Specimen U S N M 9 2 5 3 6 The
two
cranidia
deposit
over
the
Middle
Ordovician
Hillier
Limestone
M e m b e r o f the Trenton G r o u p and under the Upper Ordovician from
the
Middle
Ordovician
Black
Utica Shale. T h e species has s o m e distinct differences from
River, H e r k i m e r C o u n t y , are part of the H u r l b u r t collection
C.
and are quite possibly f r o m the s a m e exposures, Buck's Quarry,
Ceraurus? from a q u a r r y in the middle T r e n t o n , near Water-
from
town,
which Walcott got m o s t
of his
Black River trilobites.
pleurexanthemus. Jefferson
Plate County.
80
illustrates
These,
and
another some
unidentified
o f the
museum
An u n n u m b e r e d s p e c i m e n in the U S N M is f r o m the M i d d l e
materials designated as Ceraurus, need to be redescribed. T h e
Ordovician Lowville (Black River) or basal Trenton at a n o w -
s p e c i m e n s differ f r o m C. plcurexanthemus in the larger eye, the
a b a n d o n e d railroad cut 3.2 km (2 miles) b e l o w Poland, H e r k i m e r
m o r e p r o m i n e n t tubercles on the glabella, and inward-curving
County.
genal spines.
ORDER
PHACOPIDA
135
Cheirurus sp. (Hall, 1 8 6 7 ) Plate 81
Gabriceraurus
Specimen N Y S M 9 6 9 3
f r o m C. pleurexanthemus in that the f o r m e r has raised tubercles
Lower
Silurian
Rochester Shale.
Rochester
Shale
was
Hadromeros
niagarensis,
previously a
Wisconsin
The
cheirurid
assigned
to
species.
the
from
(Pribyl
et
al.
1985).
Gabriceraurus
hudsoni
differs
the
on the fixed cheeks, whereas the latter free cheek is pitted. For
cheirurid
location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) . R a y m o n d ( 1 9 2 5 , p. 139,
Holloway
(1980)
140) reported the species also f r o m Virginia and Tennessee.
noted that the New York s p e c i m e n s are of the genus Cheirurus and are different from the W i s c o n s i n specimens. T h e trilobite has
Heliotnera
a long, inflated glabella that expands toward the front where it
Holotype Y P M 2 3 3 2 6
overhangs the anterior border. T h e glabellar furrows are straight,
(Heliomeroides)
Hcliomera
akocephala
akocephala
is
an
(Shaw,
uncommon
1968)
trilobite
from
the
and the basal lobe is isolated. T h e pygidium has a single m e d i a n
Middle O r d o v i c i a n , u p p e r m o s t lower and lowermost middle
spine and three pairs of long, curved, pointed lateral spines.
Chazy. O n l y cranidia are clearly identified. For location i n f o r m a tion, see Shaw ( 1 9 6 8 ) .
Deiphon pisum (Foerste, 1 8 9 3 ) Plate 8 4 B
Kawina? chazyensis
Specimen U S N M 8 8 6 4 8 T h e U S N M specimen is f r o m L o c k p o r t , Niagara C o u n t y , and labeled D. forbesi, an English trilobite not k n o w n from New York. T h e glabella is greatly inflated and covered with pustules. T h e fixigenae are reduced to long genal spines. T h i s genus is not b e n t h i c but lived in the water c o l u m n (pelagic). Forteyopsl(?)
approximus
(Raymond,
T h i s trilobite is k n o w n o n l y from cranidia in the Middle (1968). 1865)
Lectotype G S C 6 6 9 ( W h i t t i n g t o n 1 9 6 3 )
1905)
Type species. Kawina vulcanus is identified as a New York trilo-
This trilobite is k n o w n f r o m two cranidia f r o m the Middle Ordovician Chazy G r o u p . F o r location i n f o r m a t i o n , see Shaw (1968). (Raymond and
1905)
O r d o v i c i a n Chazy L i m e s t o n e . F o r location i n f o r m a t i o n , see Shaw
Kawina vulcanus ( B i l l i n g s ,
Holotype Y P M 2 3 3 0 0
Gabriceraurus dentatus
(Raymond,
H o l o t y p e C M 1277
Barton,
bite f r o m a single s p e c i m e n , n o w lost, described by R a y m o n d ( 1 9 0 5 ) . T h e type is from N e w f o u n d l a n d . Shaw ( 1 9 6 8 ) questioned that this is a M i d d l e O r d o v i c i a n Chazy trilobite. Nieszkowskia? satyrus
1913)
(Billings,
1865)
H o l o t y p e G S C 1087
Plates 8 2 and 8 3
T h i s distinctive c h e i r u r i d o f the M i d d l e Ordovician Chazy
Holotype G S C 1775 is lost; paratype M C Z 1 0 0 8 0 2 T h e paratype is from Watertown, Jefferson County. Gabriceraurus dentatus is a large cheirurid f r o m the M i d d l e Ordovician Trenton. Specimens are f o u n d mostly in the lower Trenton but have been collected well up into the group. It is n o w h e r e as c o m m o n as C. pleurexanthemus. It is distinguished by its significantly larger size and the eyes, which are set farther b a c k on the cranidium than they are in the m o r e c o m m o n C. pleurexanthemus. T h i s trilobite is also found in the B o b c a y g e o n F o r m a t i o n of O n t a r i o and in the upper Esbataottine F o r m a t i o n , District of
L i m e s t o n e has a raised, c o n e - s h a p e d glabella similar to those on s o m e lichids. F o r location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) . Sphaerexochus
(Parvixochus)
parvus
1863)
Type species. Sphaerexochus parvus is widely distributed in the Middle O r d o v i c i a n , lower a n d middle Chazy L i m e s t o n e o f the C h a m p l a i n Valley. T h e small trilobite has an inflated glabella and long genal spines. F o r location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
Mackenzie, Canada. S p e c i m e n s are also f o u n d in the Midwest; see
Sphaerocoryphe goodnovi
D e M o t t ( 1 9 8 7 ) . T h e specimen in Plate 83 is f r o m the upper
Lectotype Y P M 2 3 3 0 4 (Shaw 1 9 6 8 )
Trenton Lindsay F o r m a t i o n in O n t a r i o and is flattened, as o n e
(Billings,
H o l o t y p e G S C lost, hypotype G S C 1330
(Raymond,
Sphaerocoryphe goodnovi,
from
the
1905) Middle
Plate
86A
Ordovician
Chazy,
often finds specimens on bedding planes. Plate 82 illustrates a
as with all trilobites of this genus, has a highly inflated glabella,
specimen from the lower Trenton of Fulton C o u n t y with a m o r e
which stands well above the plane of the body. T h e specimen
three-dimensional aspect.
figured by Shaw ( 1 9 6 8 ) differs f r o m others in the genus in that the glabella appears oval in a dorsal view, while o t h e r New York
Gabriceraurus hudsoni ( R a y m o n d ,
1905)
Plate 8 4 A
Sphaerocoryphe
Holotype C M 1271
species
have
a
spherical
glabella.
For
location
i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
Shaw ( 1 9 6 8 ) identified G. hudsoni as the only cheirurid of the genus Ceraurus in the Middle Ordovician Chazy and the
other
two
species
reported,
Ceraurus
pompilius
placed Billings,
Sphaerocoryphe
major
(Ruedemann,
1901)
Holotype N Y S M 4813
R a y m o n d , 1 9 0 5 , and C. granulosus R a y m o n d and B a r t o n , 1 9 1 3 ,
T h i s is o n e of the unusual trilobites f o u n d in Middle O r d o -
in synonymy. Later investigators placed this trilobite in the genus
vician Trenton pebbles within the Rysedorph Hill C o n g l o m e r a t e ,
136
THE
Rensselaer County. It is larger than S. robusta but resembles it in general.
TRILOBITES
Family Dalmanitidae Dalmanitids are characterized as follows: T h e y have flattened bodies. T h e genal spines are often present. T h e abaxial end of the
Sphaerocoryphe robusta
(Walcott,
1875)
t h o r a c i c segments is well defined, often f o r m i n g small, pointed
P l a t e 85
Holotype M C Z 111709, specimen M C Z 110901
lappets. T h e glabellar lobes are well defined. Dalmanitids have
Walcott ( 1 8 7 5 b ) first described this small trilobite f r o m his
large cephala and pygidia and schizochroal eyes, which in most
collecting in the W a l c o t t - R u s t Q u a r r y , H e r k i m e r C o u n t y , located
cases are large. In New York they are found in the Silurian
in the Middle O r d o v i c i a n Rust M e m b e r , Trenton G r o u p . T h e
through the Middle Devonian. M a n y trilobites listed in the Trea-
trilobite is u n m i s t a k a b l e , with its spherical glabella raised well
tise as dalmanitids were assigned to the family Synphoriidae
above the plane of the body. It is not c o m m o n in the quarry, but
(Lesperance 1 9 7 5 ) . A defining difference between Dalmanitidae
the work by Walcott and later by Rust and H u r l b u r t resulted in
and Synphoriidae is the ratio of the distance from the cephalic
it being represented with fine s p e c i m e n s at M C Z , N Y S M , P R I ,
a p o d e m a l pit SO and SI and the distance between SI and S2
and U S N M . In New York S. robusta is f o u n d on o n l y o n e bedding
(Figure 5 . 2 ) .
plane in o n e l o c a t i o n , the W a l c o t t - R u s t Quarry. T h i s is probably due to its very small size and low c o n c e n t r a t i o n s , requiring a
Corycephalus? pygmaeus
significant area to be searched to be successful. T h e distinctive
Cotypes NYSM 4357 to 4358
glabella is also f o u n d in the Verulam ( T r e n t o n ) of O n t a r i o .
(Hall
and Clarke,
1888)
T h i s species is k n o w n from only two very small fragmentary cephala from Middle Devonian O n o n d a g a float boulders near
Staurocephalus sp.
Plate 9 1 B
Canandaigua,
Undescribed s p e c i m e n s have been f o u n d in the Rochester Shale. Presently they are o n l y k n o w n f r o m their free cheeks.
FIGURE 5 . 2 . Key c e p h a l i c differences
between
Ontario
County.
The
two
have an
elongated
glabella, and crenulations can be seen on the margins. T h e fragm e n t s are probably juveniles and even possibly meraspids.
Dalmanitidae a n d S y n p h o r i i d a e ( C a m p b e l l
1977).
A.
Glyptambon
amsdeni from Tennessee, a d a l m a n i t i d , w h e r e the ratio in d i s t a n c e b e t w e e n the a p o d e m a l pits at S2-S1 a n d S1-SO is about 1.1. This trilobite w a s u s e d b e c a u s e the a p o d e m a l pits s h o w up well in the p h o t o g r a p h . B. Anchiopella anchiops, a s y n p h o r i i d , from Ontario, C a n a d a , w h e r e the ratio in d i s t a n c e b e t w e e n the a p o d e m a l pits S2-S1 a n d S1-SO is about 1.6. This trilobite is also f o u n d in New York. Both s p e c i m e n s are in the G e r a l d Kloc collection.
ORDER
137
PHACOPIDA
Corycephalus regalis
(Hall,
1876)
i u m is triangular with 10 or 11 furrowed pleurae and 15 axial
Figure 5 . 3 A
rings with axial nodes.
Holotype A M N H 2 8 9 4 , paratype A M N H 2 9 2 4 7 T h i s trilobite, of the S c h o h a r i e Grit, Albany C o u n t y , is distinguished by the high convexity, large size, long genal spines, spat-
Dalmanites
ulate marginal denticles, and coarse t u b e r c u l a t i o n .
sp.
Plate 9 1 A
T h e s p e c i m e n is f r o m Lower Silurian R o c h e s t e r Shale found in an u n n a m e d creek in the S o d u s area, Wayne County.
Dalmanites aspinosus
(Weller,
1903)
Plate 87
Holotype Walker M u s e u m 1 0 2 4 2 This Silurian trilobite is f r o m the D e c k e r Ferry F o r m a t i o n . It was found in the Nearpass Q u a r r y 3.2 km (2 miles) south of Tristates, O r a n g e County. Dalmanites
bisigmatus
F.
russelli
(Lesperance,
1975)
Specimen A M N H unnumbered T h e referenced pygidium is f r o m the Lower Devonian Central Valley S a n d s t o n e , in O r a n g e C o u n t y , and is the only specimen
(Clarke,
k n o w n f r o m outside Q u e b e c . T h e r e are 12 pleural ribs, which
1900)
reach the margin. T h e r e are 20 axial rings and a small postaxial
Holotype N Y S M 13367/1 Lower
Forillonaria cf.
Devonian
Oriskany/Glenerie
Formation.
Only
the
pygidium has been characterized, although there is a glabella with this label in the U S N M ( U S N M 5 2 6 9 9 ) . T h e pygidium is triangular with 14 or 15 axial rings. T h e r e are p r o m i n e n t axial tubercles. T h e r e are 10 or 11 pairs of pleural ribs, which curve backward near the margins. Dalmanites limulurus limulurus
ridge. T h e surface is granular.
Neoprobilium
nasutus
(Conrad,
1841)
Figure
5.3B
Hypotypes N Y S M 4 3 4 2 t o 4 3 4 7 Type species. T h i s species is f r o m the Lower D e v o n i a n New Scotland F o r m a t i o n . T h e c e p h a l o n has a long anterior, median process that terminates in two divergent r o u n d e d spines. T h e
(Green,
1832)
Plates
88,
89,
and 9 9
genal spines are long and slender. T h e pygidium is subtriangular with 13 or 14 axial rings and 10 or 11 pleural ribs, which b e n d posteriorly toward the m a r g i n . T h e r e is a terminal spine equal
Neotype N Y S M 13381 Dalmanites limulurus limulurus is c o m m o n
in
the Lower Sil-
urian Rochester Shale of western New York in Niagara, O r l e a n s , and M o n r o e Counties (Tetreault
1 9 9 4 ) . T h e c e p h a l o n has a
distinct flattened b o r d e r and long tapering genal spines. T h e pygidium is triangular; the ribs are almost equal in width and terminate in a long slender spine. T h i s species is possibly the m o s t c o m m o n trilobite of the Rochester Shale. T h e exoskeleton is thin and often dissolved away. T h i s subspecies is f o u n d in the western exposures while D. I. lunatus, with a s h o r t e r pygidial spine, is found in the m o r e eastern exposures of the R o c h e s t e r Shale. B o t h
or greater in length than the pygidium. T h e spine is narrow, r o u n d e d in cross section, and c o m e s to a sharp point. T h e surface of the pygidium is granulose.
Neoprobilium
tridens
(Hall,
1859)
Figure
5.3C
Type A M N H 2 6 0 8 , hypotype Y P M 6 6 5 9 O n l y cephala are k n o w n of this species f r o m the Lower D e v o n ian New Scotland F o r m a t i o n . T h e cephala have a long anterior process that ends in two r o u n d e d divergent spines separated by a short, blunt, triangular process.
the specimens illustrated in Plates 88 and 89 are from the s a m e Odontochile
quarry in Orleans County.
litchfieldensis
(Delo,
1940)
Cotype U S N M 78089 Dalmanites
limulurus
lunatus
(Lambert,
Lower
1904)
Devonian,
Sallsburg
Quarry,
Litchfield,
Herkimer
County. O n l y two pygidia are k n o w n . T h e y are as wide as long
Cotypes U S N M 5 0 4 5 9 , 7 9 1 2 0 This subspecies is similar to D. I. limulurus, but the frontal
with a short acute t e r m i n a t i o n . T h e r e are 17 c o m p l e t e axial rings
process is wider and longer, the cheeks are narrower, the terminal
and 2 or 3 i n c o m p l e t e o n e s . Each ring bears an irregular row of
spine width and length are equal, and the posterior rib b r a n c h e s
tubercles. T h e r e are 14 pleural furrows, each lobe with a row of
are larger. This trilobite is f o u n d farther east in the R o c h e s t e r
tubercles along the crest. T h e b o r d e r is granulose.
Shale, in Oneida County, than the m o r e c o m m o n D. I. limulurus. Odontochile Dalmanites
(Synphoroides?)
pleuroptyx
(Green,
1832)
(Green,
1832)
Plate
92
T h i s species from the Lower D e v o n i a n C o e y m a n s Limestone
Plate 9 0 Plastotype U S N M 6 2 4 8 6
micrurus
Holotype N Y S M 13385 in
Herkimer
County
may
be
part
of
the
genus
Huntonia
T h i s trilobite from the Lower Devonian Helderberg G r o u p is
( C a m p b e l l 1 9 7 7 ) . T h e surface o f the c e p h a l o n i s o r n a m e n t e d
listed from both the New Scotland Beds and the Kalkberg L i m e -
with small tubercles. T h e r e are moderate-sized genal spines. T h e
stone in Albany and S c h o h a r i e C o u n t i e s . T h e cephalon has a
pygidial axis has 17 rings and there are 13 or 14 pleural ribs. T h e
broad crenulated frontal expansion and genal spines. T h e pygid-
pygidium terminates in a short spine.
FIGURE 5.3. Trilobites of the families D a l m a n i t i d a e ( A - D ) a n d S y n p h o r i i d a e ( E - G ) from the Lower a n d lower M i d d l e D e v o n i a n . A. Corycephalus regalis from the "Schoharie Grit" of A l b a n y County. The f i g u r e d c e p h a l o n is from Hall a n d Clarke (1888). B. Neoprobilium nasutus from the New S c o t l a n d Formation. The figured c e p h a l o n a n d p y g i d i u m are from Hall ( 1 8 6 1 b ) . C. Neoprobilium tridens from the New Scotland Formation. The f i g u r e d s p e c i m e n is from Clarke (1908) a n d is YPM 6 6 5 9 . D. Phalangocephalus dentatus from the Port Jervis Limestone in O r a n g e County. All three figures, a nearly c o m p l e t e trilobite a n d a c e p h a l o n a n d p y g i d i u m , are from Hall a n d Clarke (1888). E. Synphoria stemmata stemmata from the Oriskany/Glenerie Formations, C o l u m b i a County. The three s p e c i m e n s , a c e p h a l o n in dorsal a n d front view a n d a p y g i d i u m , are from Clarke (1900). F. Coronura myrmecophorus from the O n o n d a g a Limestone at Kingston, Ulster County. The p y g i d i u m f i g u r e d is from Hall a n d Clarke (1888). G.
Trypaulites calypso from the
C o l u m b u s Limestone, Sandusky, Ohio. The trilobite is also reported from N e w York. The illustration is from Hall a n d Clarke (1888).
ORDER
PHACOPIDA
Odontochilephacoptyx
(Hall
139 and
Clarke,
1888)
p o o r state of preservation of the s p e c i m e n s available to Edge-
Type N Y S M 4 3 5 1
c o m b e and C h a t t e r t o n m a d e proper identification impossible. A
Only the pygidium is k n o w n f r o m this Lower Devonian
s p e c i m e n now at the PRI ( P R I 4 9 6 2 8 ) , illustrated in Plate 9 5 ,
Oriskany trilobite. Delo ( 1 9 4 0 ) also listed this trilobite from the
suggests a new species m a y be involved (Greg E d g e c o m b e 1999,
lower O n o n d a g a of C a n a d a . T h e pygidium is triangular with a
private c o m m u n i c a t i o n ) .
terminal spine. T h e r e are 13 axial rings and 16 pleural ribs. T h e surface is covered with spines or tubercles, which are m o r e closely spaced on the pleura. T h e r e are tubercles of two sizes on the axial rings: the smaller are m o r e a b u n d a n t and the larger entirely
Encrinurus sp.
Plate 96
T h e unidentified s p e c i m e n s in Plate 96 are from the Lockport G r o u p o f Wayne C o u n t y .
obstruct the furrows. Erratencrinurus vigilans Odontochile? sp. Plate 93 T h e specimen is from the Lower D e v o n i a n , upper M a n l i u s F o r m a t i o n , Cobleskill, S c h o h a r i e County. Phalangocephalus dentatus
1847)
Plate 94
(Barrett,
1876)
vigilans
is
found
in
the
lower
half of the
Figure 5 . 3 D
pygidium.
Type species. T h i s species is characterized by the n u m e r o u s dant in the Port Jervis L i m e s t o n e southeast of Port Jervis in O r a n g e C o u n t y that the locality has been referred to as Trilobite M o u n t a i n . T h e cephalic b o r d e r has 37 spines; the longest is medial and the shortest is on the flank of the genal spine.
trilobites.
The
glabella has near-parallel sides or expands forward. T h e t h o r a x has 10 to 12 segments. T h e t h o r a c o p y g i d i u m is generally well tapered and may appear subtriangular. T h e small
Erratencrinurus
cybeleform
(Raymond
1921),
listed
by Fisher ( 1 9 6 5 ) f r o m the M i d d l e O r d o v i c i a n , lower Trenton Larrabee L i m e s t o n e , and E.
trentonensis
(Walcott
1 8 7 7 ) , des-
cribed with material f r o m W i s c o n s i n and Illinois, are j u n i o r s y n o n y m s of E. vigilans. T h e r e is u n n u m b e r e d material in the U S N M , all f r o m the M i d d l e O r d o v i c i a n , lower T r e n t o n , labeled Encrinurus
trentonensis.
Also
the
ROM
has
an
entire
specimen
( R O M 1 8 7 3 5 ) s o labeled.
Family Encrinuridae pustulose
Herkimer
C o u n t y . It is a small very pustulose trilobite with a highly tapered
triangular marginal spines. Pieces of this trilobite are so a b u n -
are generally small
Erratencrinurus
Middle O r d o v i c i a n Trenton G r o u p , particularly in
Hypotypes N Y S M 4 3 1 0 t o 4 3 1 1
Encrinurids
(Hall,
Lectotype A M N H 3 6 0 7 0 ( D e M o t t 1 9 8 7 ) , s p e c i m e n N Y S M 17008
pygidium
usually has very-well-defined pleural ribs, and the pygidial axis has significantly m o r e lobes than there are pleural ribs.
Physemataspis insularis (Shaw,
1968)
Plate 8 6 D
H o l o t y p e N Y S M 12331 Physemataspis
insularis
is
found
in
the
Middle
Ordovician,
lower middle Chazy t h r o u g h o u t the C h a m p l a i n Valley. For location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) . It is a small trilobite described from silicified material with very g o o d detail. T h e c r a n i d i u m is very pustulose on the glabella and palpebral area, while the genal area is pitted. It has a spherical glabella and eyes raised on stalks
Cybeloides ella ( R a y m o n d and Narraway)
well above the plane of the body.
Specimen M C Z 5 0 9 3 T h e listed specimen is from the Middle O r d o v i c i a n Black River Group at Buck's Q u a r r y northeast of Poland, H e r k i m e r County.
Family Homalonotidae T h e h o m a l o n o t i d s as a family are k n o w n from the Lower Ordovician to the end of the M i d d l e D e v o n i a n . All currently
Cybeloides prima ( R a y m o n d , 1 9 0 5 ) Plate 8 6 B
k n o w n New York species b e l o n g to the subfamily H o m a l o n o t i n a e
Lectotype C M H I 2 8 6 (Shaw 1968) Cybeloides prima is a small e n c r i n u r i d trilobite of the M i d d l e
that is represented from the Lower Silurian through the Middle
Ordovician, lower and middle Chazy. It apparently is geographi-
D e v o n i a n . T h e h o m a l o n o t i n s are characterized by a largely fea-
cally restricted to the area of Valcour and the southern end of
tureless c e p h a l o n and a r o u n d e d , subtriangular pygidium. There
Valcour Island, Clinton County. T h e cephalon has long curved
are facial sutures, but the c e p h a l o n on the New York h o m a -
genal spines and a medial occipital spine. T h e pygidium is dis-
lonotids is always f o u n d intact, indicating that the free cheeks
tinctive, as the anterior pleurae curve posteriorly and b a c k toward
were fused and not lost d u r i n g the m o l t i n g process.
the axis. Specimens described by Shaw are silicified r e m a i n s . No Brongniartella
articulated specimens are k n o w n .
trentonensis
(Simpson,
1890)
S p e c i m e n N Y S M 17017 Encrinurus cf. E. raybesti ( E d g e c o m b e a n d C h a t t e r t o n , 1 9 9 3 )
This
is a
Middle Ordovician
Trenton
age trilobite from
Plate 95
Pennsylvania. A l t h o u g h S i m p s o n reported it, Collie ( 1 9 0 2 ) first
PRI 4 9 6 2 8
described it. T h i s trilobite is f o u n d locally a b u n d a n t in the Salona
Lower Silurian, Reynales L i m e s t o n e , Niagara County. T h i s limestone is m u c h older than that c o n t a i n i n g E.
raybesti. T h e
F o r m a t i o n limestones at the Rte. 3 2 2 bypass at State College, Pennsylvania.
The
position
of these
limestones
is
possibly
140
THE
TRILOBITES
equivalent to the Kings Falls F o r m a t i o n of the T r e n t o n G r o u p in
however, disarticulated pieces are not u n c o m m o n . T h e specimen
New York. T h e Pennsylvania limestones were deposited in deeper
shown
water than those of New York, indicating that the presence of this
Trimeras delphinocephalus is also
trilobite is facies controlled. T h e r e is no reason why B. trento-
E n g l a n d , suggesting that protaspis was pelagic.
in
Plate
99
is
accompanied found
by
in
Dalmanites
limulurus.
the Silurian beds
in
nensis might not be an occasional m i g r a n t into the New York rocks.
Trimerus
vanuxemi
(Hall,
1859)
Type A M N H 2 6 1 4 / 1 , 2 Dipleura dekayi ( G r e e n , 1 8 3 2 ) Plates 97 a n d 98
T h i s large h o m a l o n o t i d is from the Lower Devonian, lower
Hypotypes N Y S M 4 4 7 8 t o 4 4 8 7 Type
species.
Dipleura
Helderberg and the Oriskany in O r a n g e County. Only pieces are in
k n o w n , but Hall and Clarke's ( 1 8 8 8 ) reconstruction 2 7 . 9 c m is (11
Middle Devonian, H a m i l t o n siltstone deposits. In s o m e areas
dekayi
is
most
often
found
inches) long. It is not at all clear what differentiates this trilobite
the cephala and pygidia are c o m m o n . W h o l e , articulated speci-
from
Homalonotus
major.
m e n s are far less c o m m o n , b u t in certain central New York m u d s t o n e s they are quarried successfully. T h i s m u c h - s o u g h t -
Family Phacopidae
after trilobite has been f o u n d in significant n u m b e r s f r o m the
Phacopids are the best k n o w n of all New York trilobites
famous " C o l e Hill Road b e d s " in M a d i s o n C o u n t y . T h e p a r t i c u -
because of the widespread availability of Eldredgeops rana in New
lar specimen shown in Plate 97 is from m o r e western exposures
York M i d d l e D e v o n i a n rocks. T h e family occurs from the Lower
of Kashong Shale and shows healed d a m a g e on the right side.
Silurian through the Upper D e v o n i a n , but the Lower and Middle
T h e r e is no o t h e r H a m i l t o n trilobite that can be c o n f u s e d or m i s -
Devonian trilobites are the best k n o w n . T h e glabella is rounded
taken for D. dekayi. Dipleura dekayi can be f o u n d in s p e c i m e n s
and expands forward. Phacopids have schizochroal eyes. T h e
up to 15.2 cm (6 inches) or longer. In size, however, it c a n n o t
genal angle is usually r o u n d e d , but short spines have been
compete
Homalonotus
observed on s o m e of the Lower Devonian species. T h e facial
major). T h e s p e c i m e n illustrated in Plate 98 shows large, spar-
sutures are fused, and molted cephala are c o m p l e t e . M u c h of
filled t h o r a c i c perforations that e x t e n d through to the internal
the diagnosis of phacopids relies on cephalic features such as
mold.
glabellar furrows and p r o s o p o n . T h e glabellar furrow SI can be
with
its
Lower
Devonian
cousin
(i.e.,
c o m p l e t e across the glabella, f o r m i n g a preoccipital ring; it can Homalonotus
major
(Whitfield,
1885)
extend back to the occipital ring ( S O ) , cutting o f f the first glabel-
Hypotype N Y S M 4 4 9 3
lar lobe ( L I ) into a n o d e ; or it can be a crease that does not cross
Two large, i n c o m p l e t e s p e c i m e n s of a h o m a l o n o t i d were
the glabella or j o i n the S O . T h e S2 and m o r e anterior glabellar
discovered in the upper part of the Lower D e v o n i a n Oriskany
furrows may be faintly expressed or absent. T h e thoracic pleurae
Sandstone near Kingston, D u t c h e s s C o u n t y . T h e larger s p e c i m e n
have rounded ends and the pygidium is semicircular. Maximova
is in the N Y S M and the smaller was given to a local, Kingston
( 1 9 7 2 ) erected a new genus, Paciphacops, and two new subgenera,
m u s e u m . Whitfield, when describing the new species, calculated
Paciphacops
that the smaller of the two, if c o m p l e t e , would have m e a -
Phacops logani and Phacops pipa,
and
sured 3 9 . 4 c m ( 1 5 . 5 inches) l o n g b y 1 4 c m ( 5 . 5 inches) wide.
We have elected
Hall and Clarke ( 1 8 8 8 ) pictured this s p e c i m e n as it might be
labels rather than subgeneric ones. Struve ( 1 9 9 0 ) differentiated
c o m p l e t e , and added the additional c o m m e n t s that the smaller
Phacops rana f r o m the type species Phacops latifrons and erected
specimen was from the lower O r i s k a n y and the larger, type spec-
the new genus Eldredgeops for the "Phacops" species of eastern America;
Viaphacops, to
with
two
as the
New
use Paciphacops and
consequently the
York
phacopids,
respective type species. Viaphacops as generic
imen was from the upper. We are not aware of any additional
North
specimens.
listed here may be referred to Eldredgeops when this genus is
Middle
Devonian
Phacops?
b e t t e r defined for N o r t h A m e r i c a . Struve ( 1 9 9 0 ) also reassigned Trimerus delphinocephalus
(Green,
1832)
Plate 99
Hypotypes N Y S M 4 4 9 0 t o 4 4 9 2 Type species.
Trimerus delphinocephalus is a w e l l - k n o w n trilo-
o n e of the Viaphacops species to Burtonops. Tables 5.5 and 5.6 list the I eat u res ol the Lower and Middle I levonian phacopids in New York.
bite of the Lower Silurian Rochester Shale. Gillette ( 1 9 4 7 ) , in his faunal list, restricted it in New York to the upper C l i n t o n G r o u p ,
Burtonops cristatus
and it is f o u n d across the state in o u t c r o p s of this age. In the
Lectotype N Y S M
Rochester Shale it is mostly f o u n d in the upper, deeper-water
4612
(Hall,
1861)
13883/1
Figure 5 . 4 F
(Eldredge
1 9 7 3 ) , hypotype N Y S M
facies (Tetreault, 1 9 9 4 ) . T h i s large inflated trilobite has a trian-
Type species. T h i s phacopid is from the Lower Devonian
gular cephalon and small eyes. T h e axial lobe on the t h o r a x is very
S c h o h a r i e F o r m a t i o n . Exposures are found in S c h o h a r i e County.
wide and faint. T h e pygidium has a distinct axial lobe, triangular
T h e c e p h a l o n has large genal spines and usually an occipital
and tapering to a point. T h i s trilobite is rarely f o u n d whole;
spine. T h e t h o r a x has axial spines. T h e r e are 14 dorsoventral rows
ORDER
PHACOPIDA
141
Table 5.5. Features of the Lower Devonian phacopids from New York
Cephalon Glabellar shape in "standard orientation" Posterior region of the glabella
Glabellar ornamentation
Dorsoventral files in the eye Ornamentation of the cephalic doublure
Genal spine Occipital spine Thorax Thoracic axial spines Axiallateral lobes Stratigraphic unit
Paciphacops logani
Paciphacops hudsoniscus
Paciphacops clarkei
Paciphacops subspecies A
Phacops? clarksoni
Burtonops cristatus
High (tumid)
High
Flattened
Flattened
Flattened
Relatively tumid
Deeply incised and connected 1S glabellar furrows; forms conspicuous intercalating ring with distal nodes and a median node, which is recurved slightly anteriorly
Deeply incised and connected 1S glabellar furrows; forms conspicuous intercalating ring with distal nodes and a median node, which is recurved slightly anteriorly
Deeply incised and connected 1S glabellar furrows; forms conspicuous intercalating ring with distal nodes and a median node, which is recurved slightly anteriorly
Deeply incised and connected 1S glabellar furrows; forms conspicuous intercalating ring with distal nodes and a median node, which is recurved slightly anteriorly
Glabellar lobes 1L are present distally as nodes; the intercalating either is wholly absorbed into the composite glabellar lobe or is depressed, with the medial position of glabellar furrow 1S generally obsolescent
Ground mass of small granules that cover the large tubercles and spaces between them 17, occasionally 18
Ground mass of small granules that cover the large tubercles and spaces between them 15 or 16
Small tubercles and ground mass of granulation much finer
Large simple tubercles, generally of different size classes
Intercalating ring depressed distally; medial lobes reflected anteriorly and incorporated into composite grabellar lobe; glabellar furrow 1S confluent with occipital furrow distally, then reflected anteromedially, becoming obsolescent medially Large simple tubercles, generally of different size classes
17
14
Granules covering the entire surface proximal to the furrow
Granules covering the entire surface proximal to the furrow
Present Node
Absent ?
Present Absent
Absent 7
Large Absent
Retains granules anteromedially but develops connected granules posterolaterally Large Present
Absent
?
Absent
?
?
Spines or nodes
Well developed
?
?
?
9
Faint
Kalkberg and New Scotland Formations
Kalkberg and New Scotland Formations
Glenerie Formation
Bee raft Formation
Schoharie Formation
Schoharie Formation
18
15
Source: From Eldredge, 1973; Campbell, 1977; Delo, 1940.
in the eyes, with a total of 48 to 81 lenses. T h e illustrated lectotype is from Eldredge ( 1 9 7 2 ) .
quarries near Silvania, O h i o . S p e c i m e n s of this trilobite were identified f r o m the Solsville M e m b e r ( n o w recognized as the Pecksport M e m b e r ) o f the H a m i l t o n G r o u p i n M a d i s o n C o u n t y
Eldredgeops crassituberculatus ( S t u m m , 1 9 5 3 ) Plates 1 0 0 ,
(Eldredge 1 9 7 2 ) . T h i s trilobite has 18 dorsoventral files, with six,
H O D , a n d 111
rarely seven, lenses per file. T h e interlensar sclera is well devel-
Holotype U M M P 2 5 5 3 7
o p e d , and the lenses are generally flush with the scleral surface.
This Middle Devonian phacopid is f o u n d in great n u m b e r s along with E. milleri (Plates 110F, 111) in the f a m o u s Silica Shale
Cephalic tubercles are large and often elongated. Plate 100 shows a specimen f r o m O h i o .
THE
142
TRILOBITES
Table 5.6. Features of the Middle Devonian phacopids of New York Viaphacops bombifrons
Viaphacops canadensis
Phacops? iowensis
Eldredgeops rana
Relatively tumid
Flattened
Flattened
Flattened
Intercalating ring depressed distally; medial lobes reflected anteriorly and incorporated into composite grabellar lobe; glabellar furrow 1S confluent with occipital furrow distally, then reflected anteromedially, becoming obsolescent medially Large simple tubercles, generally of different size classes
Intercalating ring depressed distally; medial lobes reflected anteriorly and incorporated into composite grabellar lobe; glabellar furrow 1S confluent with occipital furrow distally, then reflected anteriomedially, becoming obsolescent medially
Deeply incised and connected 1S glabellar furrows; forms conspicuous intercalating ring with distal nodes and a median node, which is recurved slightly anteriorly
1S deeply incised
Large simple tubercles, generally of different size classes
Rounded tubercles becoming transversly elongate at the anterior margin of the glabella
Dorsoventral files in the eye
14, rarely 13, 15, 16
13 or 14
13
18 in E. r. crassituberculata
Ornamentation of the cephalic doublure
Retains granules anteromedially but develops connected granules posterolaterally Short Absent
Large Absent
Absent Absent
Absent Absent
Sometimes nodes
Absent
Absent
Absent
Faint
?
Absent
Absent
Onondaga Formation
"Lower Onondaga Limestone," Port Colborne, Ontario
Hamilton Group
Hamilton Group
Cephalon
Glabellar shape in "standard orientation" Posterior region of the glabella
Glabellar ornamentation
15, rarely 16 or 17 in E. r. norwoodensis 17 in E. r. rana
Genal spine Occipital spine
Shows only terrace lines
Thorax
Thoracic axial spines Axial-lateral lobes Stratigraphic unit
Source: From Eldredge, 1972, 1973; Delo, 1940. Eldredgeops rana ( G r e e n , 1 8 3 2 ) Plates 1 0 1 , 1 0 2 , 1 0 3 , 1 0 4 , 1 1 0 C ,
103 are of trilobite clusters f o u n d in trilobite-rich beds, all in
and 111
western New York. Clusters such as these have been described as
Holotype N Y S M 4 6 4 5 Eldredgeops rana is the single most c o m m o n trilobite f o u n d and collected in New York, being widely distributed in the Middle
m o l t i n g or breeding assemblages. Plate 104 illustrates an E. rana with c o l o r centers that may reflect underlying muscle a t t a c h m e n t areas.
Devonian H a m i l t o n G r o u p shales and limestones and reported up into the Upper D e v o n i a n C h e m u n g rocks. T h e eye has 17
Eldredgeops
dorsoventral files. T h e most productive localities are in the
a n d 111
norwoodensis
(Stumm,
G r a b a u Trilobite Beds in the W a n a k a h Shale. T h e s e r e m a r k a b l e
Holotype U M M P 25524
1953)
Plates
110E
beds are well exposed in Erie, G e n e s e e , and Livingston C o u n t i e s .
T h i s is a trilobite of the late Middle D e v o n i a n . In New York
T h e exuviae, cephala, and pygidia are ubiquitous in the H a m i l -
it is only f o u n d in the Tully F o r m a t i o n , T o m p k i n s County. T h e
t o n G r o u p , and entire s p e c i m e n s are c o m m o n . Plate 101 shows
eye with usually has 15, but rarely 16 or 17, dorsoventral files.
the holotype (positive) and its m o l d (negative). Plates 102 and
T h i s species is distinguished f r o m E. rana by the narrower, less
FIGURE 5.4. Lower Devonian a n d lower M i d d l e D e v o n i a n p h a c o p i n s . All the figures are c e p h a l a s h o w n in dorsal a n d side views. The 1-cm scale bar is the s a m e for all the i m a g e s . A. Phacops? clarksoni from the Schoharie Formation, S c h o h a r i e County. The illustrated c e p h a l o n is A M N H 2 9 2 4 4 , the holotype. B. Paciphacops hudsoniscus, the s m a l l - e y e d form from the K a l k b e r g - N e w S c o t l a n d Formations, H u d s o n , C o l u m b i a County. The illustration is A M N H 2613. C. Paciphacops logani, the l a r g e - e y e d form from the New Scotland Formation near Schoharie, Schoharie County. D.
Paciphacops logani clarkei
from the Murailles Formation, Perce, Q u e b e c . This s u b s p e c i e s is also f o u n d in the Glenerie Formation, H u d s o n , C o l u m b i a County. Illustrated is A M N H 2 9 2 4 0 , the holotype. E.
Viaphacops bombifrons from
the O n o n d a g a Formation, w e s t e r n N e w York. The illustrated s p e c i m e n is A M N H 4077/2A, the lectotype. F. Burtonops cristatus from the S c h o h a r i e Formation, N e w York. Illustrated is A M N H 1 3 8 8 3 / 1 , the lectotype. A - F are from E l d r e d g e (1973), R e p r o d u c e d with p e r m i s s i o n of the author.
144
THE
TRILOBITES
e x p a n d i n g forward glabella and by the s m o o t h pygidial pleura.
distal
T h e interpleural furrows on the pygidium are deeply incised.
Eldredge ( 1 9 7 3 ) described a large-eyed and a small-eyed form.
p o r t i o n s of the t h o r a c i c
rings are large and distinct.
A l t h o u g h Eldredge ( 1 9 7 2 ) did not c o m m e n t on it, he illustrated
Further work has the large-eyed f o r m , with 17 or 18 dorsoven-
what could be considered a large- and small-eyed f o r m , with the
tral files and an average of 94 individual lens, described as
New York specimen being small-eyed.
P. logani (Plate 1 0 7 ) , and the small-eyed f o r m , with 15 or 16 dorsoventral files and with 46 to 48 lens, described as P. hud-
Eophacops
(Acernaspis?)
trisulcatus
(Hall,
1843)
Plates
105
soniscus ( R a m s k o l d and Werdelin 1 9 9 1 ) . T h i s species is reported
and 106
from the Kalkberg and New Scotland F o r m a t i o n s ot Schoharie
Holotype A M N H 1594
and C o l u m b i a C o u n t i e s , and also in Q u e b e c . Plate 107 shows a
T h i s trilobite is found in the Lower Silurian shales in M o n r o e
partially disarticulated specimen from the Helderberg G r o u p . SI
County. Ludvigsen ( 1 9 7 9 b ) figured a Silurian p h a c o p i d , referred
extends across the glabella, leaving LI as a ring on the posterior
to as an Acernaspis species, f r o m the Cataract G r o u p and the
of the glabella just anterior to the occipital ring. T h e specimen
T h o r n l o e F o r m a t i o n of C a n a d a . T h e C a n a d i a n phacopid has a
also has acute genal angles. In addition, note the p r o m i n e n t cir-
weakly inflated glabella with three pairs of t h i n , curving lateral
cular lobes on the t h o r a x where the axial and pleural lobes meet.
furrows. T h e pygidium is small and lenticular, with few furrows.
S p e c i m e n s illustrated by Hall ( 1 8 6 1 a , b ) have genal angles from
New York s p e c i m e n s are usually poorly preserved a n d are not
rounded to acute.
inconsistent with this description. F u r t h e r research is needed to properly classify the New York s p e c i m e n s . T h i s p h a c o p i d is not
Paciphacops logani s u b s p . A
u n c o m m o n in the W i l l i a m s o n or Sodus shales underlying the
Specimen A M N H 29243
(Eldredge,
1973)
Irondequoit L i m e s t o n e in M o n r o e C o u n t y . Plates 105 and 106 are
Lower Devonian Becraft F o r m a t i o n near S c h o h a r i e , Schoharie
examples of this trilobite. Preservation of the exoskeleton is u n i -
County. T h i s species is based on a single cephalon with a dis-
formly poor.
tinctive eye. T h e r e are 15 dorsoventral files with a total of 73 lenses.
Paciphacops
hudsoniscus
(Hall,
1859)
Figure
5.4B
Type A M N H 2 6 1 3
Phacopina
T h i s trilobite is reported f r o m the Lower Devonian Helderberg
Group
at
"Becraft's
Mountain"
1890)
County.
Middle Devonian O n o n d a g a L i m e s t o n e , Cayuga, O n t a r i o . T h e h o l o t y p e is a small, exfoliated c e p h a l o n . T h e presence in New
logani, the small-eyed
York is suspected b u t not k n o w n .
Ramskold
Columbia
(Clarke,
Eldredge ( 1 9 7 3 ) s y n o n y m i z e d the species with Paciphacops logani form.
in
anceps
Holotype NYSM 4 6 0 9
and
Werdelin
(1991)
rejected this, and P. hudsoniscus is n o w considered a legitimate species.
Phacopina?
correlator
(Clarke,
1900)
Holotype N Y S M 13882/1 Paciphacops clarkei
(Eldredge,
1973)
Figure
5.4D
O n l y the holotype is k n o w n from the Glenerie F o r m a t i o n at
Holotype A M N H 2 9 2 4 0 A phacopid of the Lower D e v o n i a n Glenerie
Becraft M o u n t a i n . It is a m o l d of the left half of the cephalon. Formation,
Becraft M o u n t a i n , C o l u m b i a C o u n t y . T h e glabella is s o m e w h a t
Phacops? clarksoni (Eldredge,
flatter than in o t h e r P. logani subspecies. T h e genal spines are well
Holotype A M N H 29244
developed. Glabellar furrow SI generally is indistinct medially,
1973)
Figure 5.4A
A species based on seven distinctive cephala from the Lower
and the intercalating ring tends to be i n c o r p o r a t e d medially into
Devonian
the glabellar l o b e . T h e eyes have 17 or 18 dorsoventral files with
S c h o h a r i e County. T h e r e are large genal spines and no occipital
Schoharie
Formation
of
the
Schoharie
Valley,
eight or nine lenses per c o m p l e t e file. O r n a m e n t a t i o n is fine
n o d e . T h e eye has 17 dorsoventral files and m o r e than 80 lenses.
tubercles over the entire test that are m u c h smaller than those on
T h e lenses protrude farther beyond the interlensar sclera than is
the other subspecies.
c o m m o n for phacopids. T h e area under the visual surface is devoid of o r n a m e n t a t i o n . Eldredge believed that the specimens
Paciphacops logani ( H a l l , 1 8 5 9 ) Figure 5 . 4 C a n d Plates
107,
c a n n o t be assigned to either Paciphacops or
Viaphacops.
1 1 0 A , and 111 Lectotype N Y S M 1 3 8 8 5 / 2 (Hall a n d Clarke 1 8 8 8 ; see Eldredge
Phacops? iowensis alpenensis
1973)
a n d 111
Type species. T h i s species is a widely distributed Lower D e v o n i a n , lower Helderberg trilobite. T h e occipital n o d e is vari-
(Stumm,
1953)
Plates
108,
110F,
Holotype U M M P 25516 Eldredge ( 1 9 7 2 ) f o u n d s p e c i m e n s in the Middle Devonian
ably developed, and genal spines are usually present but m a y be
Pecksport
absent, particularly in the small-eyed f o r m . T h e nodes on the
W i n d o m M e m b e r o f the H a m i l t o n G r o u p i n Madison County.
Member.
Later Steve
Pavilski
found s o m e in the
ORDER
PHACOPIDA
145
T h e SI glabellar furrow is deeply incised. Moderately conical
resembles a dalmanitid. T h e family was reviewed by Delo ( 1 9 4 0 )
tubercles are all over the exoskeleton. T h e facial suture over the
and m o r e recently by Ludvigsen and C h a t t e r t o n ( 1 9 8 2 ) .
ocular platform is moderately deeply incised. T h i s trilobite is relatively c o m m o n in Michigan and very u n c o m m o n in New York.
Achatella achates (Billings, 1 8 6 0 ) P l a t e 115
Plate 108 is from the upper W i n d o m beds in Livingston County.
Hypotype N Y S M 4257
Viaphacops bombifrons (Hall a n d C l a r k e , 1 8 8 8 ) Figure 5 . 4 E
bite is f r o m O t t a w a , C a n a d a . T h e general outline resembles dal-
Type species. T h e h o l o t y p e of this M i d d l e Ordovician triloand Plates 1 0 9 , 1 1 0 B , a n d 111
manitids. T h e cephalon is semicircular in outline with long genal
Lectotype A M N H 4 0 7 1 / 2 A (Eldredge 1973)
spines. T h e glabella expands forward and the La lobe is pustu-
This species is widely distributed in the Middle Devonian
lose. T h e eyes are schizochroal and elevated well above the plane
O n o n d a g a Limestones and their equivalent in New York, O n t a r i o ,
of the c e p h a l o n . T h e b o d y tapers toward the rear, ending with a
and O h i o . T h e eye usually has 14 dorsoventral files, although 13
p o i n t e d t e r m i n a t i o n on the pygidium. W h o l e articulated speci-
to 16 are known. Four or five lenses per row are also the n o r m .
m e n s are f o u n d in the middle T r e n t o n , W a l c o t t - R u s t Quarry,
T h e area under the visual surface is coarsely tuberculate. T h e r e
H e r k i m e r County. It is also reported f r o m Pennsylvania and
are short genal spines and s o m e t i m e s an occipital n o d e but no
M i n n e s o t a . Plate 115 shows a s p e c i m e n f r o m the Walcott-Rust
occipital spine. Normally there are no t h o r a c i c axial nodes or
Quarry. T h i s trilobite is m o s t often f o u n d as cephala on bedding
spines.
planes where the high, schizochroal eyes are distinctive.
Family Pliomeridae
Calyptaulax annulata
T h e only pliomerid from New York is Pliomerops canadensis. T h e cephalon is semicircular with a p r o m i n e n t glabella. T h e glabella expands forward uniformly. T h e SI
(Raymond,
1905)
Lectotype C M H - 1 2 9 3 (Shaw 1 9 6 8 ) ; hypotypes N Y S M 1 2 3 6 8 t o 12392
and S2 glabellar
Calyptaulax annulata is f o u n d t h r o u g h o u t the M i d d l e O r d o v i -
furrows are deep and extend about o n e - t h i r d of the way across
cian Chazy G r o u p . In general shape and characteristics, it closely
the glabella. T h e t h o r a x tapers to the rear with 18 s e g m e n t s . T h e
resembles
pygidium is semicircular and curves sharply down all a r o u n d .
s p e c i m e n s with and without short genal spines. T h e protaspids
T h e r e are five pygidial axial rings and five pleurae separated by
and meraspids are also k n o w n (Shaw 1 9 6 8 ) . It is the only ptery-
deep interpleural furrows.
g o m e t o p i d k n o w n f r o m the New York Chazy.
C.
callicephalus f r o m
the T r e n t o n .
Pliomerops canadensis (Billings, 1 8 5 9 ) Plates 1 1 2 , 1 1 3 ,
Calyptaulax callicephalus ( H a l l , 1 8 4 7 )
and 114
Holotype A M N H 848
Lectotype G S C 1101 ( W h i t t i n g t o n 1961) Type species.
Pliomerops canadensis is f o u n d
Calyptaulax throughout
callicephalus
is
Plates
found
Shaw
illustrated
1 1 6 and
throughout
the
117 Middle
the
O r d o v i c i a n Trenton G r o u p of New York and is also reported in
Middle Ordovician Chazy in New York (for locations, see Shaw
O n t a r i o , M a n i t o b a , New Jersey, Kentucky, and M i n n e s o t a . It is
1968) and in Chazy age rocks in Q u e b e c , Tennessee, and Virginia.
especially c o m m o n in the Kings Falls L i m e s t o n e at Kings Falls on
Articulated specimens are not rare in New York and may reflect
the Deer River, Lewis County. At first glance this trilobite appears
this species's exceptionally robust exoskeleton, as this is generally
to be a p h a c o p i d . T h e m a i n differences are the c e p h a l o n , which
not the case with other Chazy trilobites. In most of the s p e c i m e n s ,
in C. callicephalus is not r o u n d e d but rather c o m e s to a blunt
the medial area is very rounded and the distal parts of the pleurae
point in front, and the pygidium, which is subtriangular rather
are perpendicular to the m a t r i x . Plate 112 shows an articulated
than r o u n d e d as in m o s t p h a c o p i d s . T h e pygidium could be mis-
specimen. T h e very robust exoskeleton c o n t r i b u t e d to its preser-
taken for that of calymenids f o u n d in the s a m e h o r i z o n s , but o n c e
vation in a high-energy e n v i r o n m e n t . Plate 113 is a side view of
again the pygidium of C. callicephalus is m o r e triangular and has
the same s p e c i m e n , showing the vaulted pleural area and the
m a n y m o r e axial rings and pleurae. A s p e c i m e n in the M C Z is
cephalic structure, which is difficult to see from the top.
labeled with this n a m e f r o m the Black River L i m e s t o n e Quarries
Family Pterygometopidae
trilobite resembling C. callicephalus f r o m the Upper Ordovician
near Poland, H e r k i m e r C o u n t y . R u e d e m a n n ( 1 9 2 6 ) reported a T h e pterygometopids, in New York, are f o u n d in the Middle Ordovician. T h e glabella expands forward, and the eyes are
Indian Ladder Shales. Plates 116 and 117 illustrate the dorsal and ventral exoskeletal a n a t o m y of this trilobite.
schizochroal. T h e genal angle is often r o u n d e d to acute, b u t Achatella and Eomonorachus species have genal spines. T h e t h o -
Calyptaulax eboraceous
racic pleurae are rounded on the ends. T h e pygidium is s o m e -
Holotype N Y S M 4767
(Clarke,
1894)
what triangular with 8 to 13 axial rings. Calyptaulax species at
A M i d d l e O r d o v i c i a n , lower Trenton (Glen Falls Limestone)
first glance appear to be phacopids, and the Achatella species
trilobite from the quarries at Rawlins Mills, Saratoga County. It
146
THE
TRILOBITES
is also reported from the Trenton pebbles of the Rysedorph C o n -
10 are strongly expressed. T h e axial rings have faint medial nodes.
glomerate
Eomonorachus
T h e r e are eight pygidial ribs on the pleura, with o n e or two thin
intermedins in that the S2 and S3 glabellar furrows do not isolate
raised areas near the m e d i o p o s t e r i o r area. T h e first four most
the L2 and L3 lobes. It has genal spines.
anterior ribs have weak intrapleural grooves. T h e interpleural
(Ruedemann
1901).
It
differs
from
grooves do not reach the m a r g i n . Chasmops? (or Sceptaspis) bebryx ( B i l l i n g s ,
1860)
Plate
118
Holotype? PRI 4 9 6 3 1 , hypotype G S C 1 3 2 6 2 , s p e c i m e n U S N M 26361
Family Synphoriidae T h e family Synphoriidae was erected from the subfamily Syn-
T h e trilobite is listed as Trenton age from O t t a w a , C a n a d a .
p h o r i i n a e ( D e l o 1935, 1 9 4 0 ) of the Dalmanitidae by Lesperance
Billings's illustration, however, was f r o m a s p e c i m e n o w n e d by
( 1 9 7 5 ) because o f recognition o f a n u m b e r o f new trilobites
Colonel Jewett. T h i s s p e c i m e n is n o w at PRI and is designated as
within the then subfamily. T h e family was earlier restricted to the
the holotype?. It is from Trenton age rocks at J a c k s o n b u r g , M o n t -
Devonian and was almost exclusively North A m e r i c a n . Campbell
gomery
Monorachus
( 1 9 7 7 ) and Holloway ( 1 9 8 1 ) substantially modified the concept
bebryx, is from near W a t e r t o w n , Lewis C o u n t y , collected by the
of the Synphoriidae. Holloway extended the family into the Sil-
U S G S in 1897. D e l o ( 1 9 4 0 ) illustrated the P R I s p e c i m e n , by
urian. T h e family is characterized by the distance between the
copying B i l l i n g s , and designated it as the type of Chasmops bebryx
cephalic a p o d e m e s , SI and S 2 , which is m o r e than 1.5 times the
but does not list it in the text of his paper. Plate 118 illustrates
distance between S O and S I (Figure 5 . 2 ) .
the
County.
holotype?.
The
USNM
specimen,
Chasmops? bebryx differs
labeled
from
Eomonorachus con-
vexus (Plate 119) in the longer palpebral lobes, the m u c h m o r e triangular pygidium, and the m u c h less strongly incised SI on C? bebryx.
T h e specimen
is very similar to the genus Sceptaspis,
which is widely reported in the Midwest and C a n a d a as Sceptaspis lincolnensis. If this is the s a m e species, then the species n a m e bebryx has priority.
Middle O r d o v i c i a n Trenton Falls, H e r k i m e r C o u n t y . T h e r e are two exfoliated cranidia on the small rock with the s p e c i m e n s . T h e left cheek and genal area are c o m p l e t e on o n e of t h e m . It has short, thin genal spines. T h e eyes are missing. T h e m a t r i x of the rock is a j u m b l e of Prasopora. On the s a m e rock are Flexicalymene intermedins
Type
species.
This
trilobite
from
the
Lower
Devonian
S c h o h a r i e Grit in Albany C o u n t y is also referred to as Anchiopsis; however,
the
Treatise
supports
Anchiopella.
The
cephalon
has
terminal spine. It has seven or eight pairs of rounded, unfurrowed
T h e h o l o t y p e is an internal m o l d labeled from " p r o b a b l y " the
Eomonorachus
120
and large eyes. T h e pygidium is triangular with a sharp, upturned
H o l o t y p e U S N M 8 9 9 8 7 , specimen PRI 4 9 6 3 2
cranidia.
Plate
rounded tubercles of two sizes, and the occipital ring has a spine
1940)
Plate 119
Ceraurus
1832)
Holotype N Y S M 4264
slender genal spines, the glabella is sparsely covered with well-
Eomonorachus convexus ( U l r i c h a n d D e l o in D e l o ,
and
Anchiopella anchiops ( G r e e n ,
The by
species
was
synonymized
Ludvigsen
and
Chatterton
with (1982)
pleural lobes and eight or nine axial rings.
Anchiopella anchiops sobrinus (Hall and C l a r k e ,
1888)
Holotype N Y S M 4243 T h i s trilobite of the Lower Devonian S c h o h a r i e Grit, Albany C o u n t y , differs f r o m A. anchiops in having a m o r e - r o u n d e d anterior m a r g i n and in lacking genal and occipital spines. Only the holotype cephalon is k n o w n , according to Delo ( 1 9 4 0 ) .
without c o m m e n t . D e l o ( 1 9 4 0 ) stated that the species differs from
intermedins in the r o u n d e d front m a r g i n , smaller s e c o n d
glabellar lobes, larger eyes, and coarser o r n a m e n t a t i o n . Different specimens
are
USNM
79015
from
Rathbun
Brook,
Oneida
County, and U S N M 7 9 0 1 4 f r o m the lower T r e n t o n quarries a t
Coronura aspectans ( C o n r a d , 1 8 4 1 ) Plates 121 and 122 Type A M N H 4 0 6 5 / 1 , hypotype N Y S M 4 3 1 6 Type
species.
This
species,
from
the
Middle
Devonian
O n o n d a g a L i m e s t o n e , is characterized by furrowed ribs and
Rawlins Mills, Saratoga C o u n t y . A s p e c i m e n with this n a m e in
regular, rather fine, o r n a m e n t a t i o n on the pygidium. A whole
the M C Z is labeled as f r o m the basal T r e n t o n near Poland,
s p e c i m e n , Plate 1 2 1 , in N Y S M is from Leroy, Genesee County. It
H e r k i m e r County. S p e c i m e n s collected f r o m the Glens Falls
is a latex pull from the external m o l d , as it retains better features
Limestone near A m s t e r d a m , M o n t g o m e r y C o u n t y , PRI 4 9 6 3 2
than the c o u n t e r p a r t .
(Plate 1 1 9 ) , show the following characteristics: T h e cephalon is proparian and the free cheeks are missing. T h e glabella is pustu-
Coronura helena ( H a l l , 1 8 6 1 ) Plate
lose. T h e palpebral lobe is crescent shaped, with a groove sepa-
Holotype A M N H 4250/1
127B
rating it from the fixed cheek. T h e occipital ring has a m e d i a n
T h i s species f r o m M i d d l e Devonian O n o n d a g a Limestone is
n o d e . T h e pygidium is subtriangular. T h e tapered axis extends
characterized by weak to obsolete tuberculation, long slender
nearly to the m a r g i n , with tapering m o r e strongly for the m o s t
lateral pygidial spines, and horizontally bifid terminal pygidial
a n t e r i o r five axial rings; there are at least 14 axial rings; the first
spines.
ORDER
PHACOPIDA
147
Coroiuira myrmecophorus ( G r e e n ,
1835)
Odontocephalus
Figure 5 . 3 F
humboltensis
(Sargent,
1953)
Specimen B M S E-16674-5
Hypotypes N Y S M 4 3 3 5 , 4 3 5 0 This trilobite o f the Middle Devonian O n o n d a g a L i m e s t o n e , Genesee County, is characterized by its very large size, u n f u r -
This
Middle
Devonian
O n o n d a g a species was discovered
d u r i n g road c o n s t r u c t i o n in Buffalo, Erie County. It is character-
rowed ribs, scattered tuberculose o r n a m e n t a t i o n , and erect ter-
ized by having 11 denticles on the anterior cephalic border, short
minal spines ( D e l o 1 9 4 0 ) .
genal spines, and a distinct b o r d e r on the pygidium with no terminal pygidial spines.
Odontocephalus aegeria (Hall,
1861)
Plate
123
Odontocephalus selenurus
Hypotype N Y S M 4 2 5 8 T h i s species from the Middle Devonian O n o n d a g a L i m e s t o n e , Erie County, is characterized by 11 spatulate denticles on the anterior cephalic b o r d e r and sharp, slender genal spines that extend back to the fourth thoracic s e g m e n t . T h e r e are 10 pygidial pleurae.
(Eaton,
1832)
Plate
125
Hypotypes N Y S M 4 3 5 9 t o 4 3 6 8 Type species. T h i s trilobite is reported
from the Middle
Devonian O n o n d a g a limestones across the state. T h e species is in need of revision. It has been characterized as having nine spatulate denticles on the c e p h a l o n . Hall a n d Clarke ( 1 9 8 8 , Plate 12) illustrated s p e c i m e n s that m a y b e l o n g to two different species or
Odontocephalus bifidus (Hall, 1 8 6 1 )
Plate
m o r p h o t y p e s . O n e f o r m illustrated in Plate 125 has a cephalon
124
with ridges on the denticles and a slight forward protrusion of
Hypotype N Y S M 4 2 7 5 T h e type specimen is from quarries in the O n o n d a g a L i m e stone, Genesee County. It is a pygidium characterized by a b r o a d flat area posterior to the axial lobe and two stout, rapidly tapering, and close together, terminal axial spines. T h e r e are seven to eight pleurae. An entire specimen from the s a m e quarries is illustrated in Plate 124. T h i s is the only k n o w n whole s p e c i m e n f r o m New York. T h e cephalon has nine spatulate denticles and short genal spines.
the anterior cephalic border. T h e pygidium is oval with short pygidial spines. T h e o t h e r f o r m , illustrated in Plate 126, has a c e p h a l o n with flat denticles, a r o u n d e d a n t e r i o r cephalic border, and very s h o r t genal spines. An associated pygidium is m o r e triangular with relatively long pygidial spines. T h e r e are at least five species in this genus. T h e characteristics are listed in Table 5.7. Odontocephalus sp. This
specimen
Plate
is
from
126 the
Middle
Devonian
Moorehouse
M e m b e r o f the O n o n d a g a L i m e s t o n e i n the LeRoy Quarry, Odontocephalus
coronatus
(Hall,
1861)
Genesee C o u n t y .
Holotype A M N H 4 0 6 4 , hypotype N Y S M 4 3 0 9 T h i s trilobite is from the Middle Devonian O n o n d a g a L i m e stone of central New York, Cayuga County. T h e c e p h a l o n is u n k n o w n . It is characterized by the pygidium, which has no border and eight pleurae. T h e r e are no terminal spines, but where they are on other o d o n t o c e p h a l i d s , there are two
rounded
pygidial extensions.
Schoharia
emarginata
(Hall,
1876)
Holotype N Y S M 4 3 1 8 Type species.
O n l y the pygidium of this trilobite is de-
finitely k n o w n from the Lower D e v o n i a n S c h o h a r i e F o r m a t i o n , S c h o h a r i e C o u n t y . It is characterized by a posterior " n o t c h , " within which the most posterior pleural ribs t e r m i n a t e . T h e r e are
Table 5.7. Features of the genus Odontocephalus of New York
Cephalon Length to width Preglabellar dentations Genal spines Pygidium Border Terminal spines
Axial rings Pleura
O. aegeria
O. bifidus
1:2 11
9
Long
Short
None
None
2, short, well separated 9
2, short, close together, parallel 8
9 or 10
O.
coronatus
O.
huboltensus
O.
selenurus
Not known
1:2 11 Short
1:2 9 Short
None None
Distinct None
Distinct 2, short, well separated 8 or 9
7 (plus one indistinct) 12
8 or 9
148
THE
TRILOBITES
approximately 17 axial rings and 15 n o n f u r r o w e d pleural ribs.
Trypaidites calypso (Hall and C l a r k e ,
O r n a m e n t a t i o n consists o f scattered pustules.
Type A M N H 4 2 4 9 / 1
Schoharia
f r o m O h i o and S c h o h a r i e , S c h o h a r i e County. N o n e of the illus-
1888)
Figure 5 . 3 G
Hall and Clarke ( 1 8 8 8 ) listed this trilobite as Lower Devonian sp.
trations in Hall and Clarke's publication are specimens from New
Specimen NYSM 4309 A single pygidium illustrated by Lesperance ( 1 9 7 5 ) is from the
York, and all of the s p e c i m e n listings from Lesperance ( 1 9 7 5 ) are
Middle Devonian O n o n d a g a L i m e s t o n e , S c h o h a r i e County. It is
f r o m O h i o , Kentucky, M i c h i g a n , and Illinois. O n e must question
characterized by a shallow posterior n o t c h , a pseudo postaxial
if this species is truly f o u n d in New York. T h e cephalon has short
ridge, and low flattened ribs. O r n a m e n t a t i o n consists of very few
genal spines and large eyes. T h e r e are 11 thoracic segments. T h e
scattered pustules.
pygidium is rounded with a well-defined border and has 11 axial rings with a r o u n d e d n o d e and 10 or 11 broad, flat, furrowed
Synphoria?
concinnus
(Hall,
pleurae.
1876)
Types N Y S M 4 3 0 7 t o 4 3 0 8 Grit, Albany
Trypaulites erinus (Hall,
County, is k n o w n only f r o m pygidia. T h e pygidium is s u b t r i a n -
Holotype N Y S M 4320
This species o f Lower D e v o n i a n ,
Schoharie
gular and very convex. T h e b o r d e r is o b s c u r e laterally but widens
F r o m the Middle
1861)
Plate
127A
Devonian O n o n d a g a G r o u p o f western
posteriorly into a short, b l u n t , triangular t e r m i n u s . T h e surface
New York in O n t a r i o , Genesee, and Erie C o u n t i e s , this trilobite
is s m o o t h . T h e r e are seven or eight axial rings and seven or eight
is k n o w n only from the pygidium. It has 12 (13?) slightly fur-
wide flat pleurae, the m o s t a n t e r i o r of which is indistinctly
rowed pleural ribs and 16 axial rings with a postaxial ridge. T h e r e
furrowed.
is a border. T h e surface is covered with granules and the termi-
Synphoria
lected from the Bois B l a n c near LeRoy, Genesee County, New
nation is slightly u p t u r n e d . Pygidia of this species have been colsopita
(Lesperance,
1975)
York.
Paratype A M N H 2 9 2 4 7 T h i s species is f r o m the Lower D e v o n i a n O r i s k a n y / G l e n e r i e F o r m a t i o n , C o l u m b i a C o u n t y . T h e cephalon is triangular in
Trypaulites
outline with p r o t r u d i n g genal angles. T h e a n t e r i o r b o r d e r has at
Holotype NYSM 4327
least 15 c r e n u l a t i o n s , with perhaps up to 19 m o r e . T h e pygidium
macrops
(Hall,
1861)
T h i s trilobite is k n o w n f r o m a single incomplete, internal
has 14 or 15 axial rings and 9 or 10 pleural ribs. It is t e r m i n a t e d
cephalic
with a blunt spine u p t u r n e d at about 30 degrees.
S c h o h a r i e County. T h e eye is m u c h larger than that of T. calypso,
m o l d from
the O n o n d a g a
Limestone o f Schoharie,
with 37 dorsoventral files of 15 lenses each. Synphoria
stemmata
compacta
(Lesperance
and
Bourque, 1971)
5.6 ORDER PROETIDA
Holotype N Y S M 4371
T h i s p o s t - C a m b r i a n order lasted until the final extinction of
T h i s trilobite, from the Lower Devonian O r i s k a n y / G r e n e r i e
trilobites at the end of the Permian. T h e trilobites are generally
F o r m a t i o n s o f Becraft M o u n t a i n , C o l u m b i a C o u n t y , resembles S .
oval to suboval in o u t l i n e , with a m e d i u m - s i z e d pygidium. Genal
stemmata stemmata except the a n t e r i o r cephalic b o r d e r has 13 to
spines are c o m m o n l y present.
19 crenulations. T h e pygidium is n o n s p i n o s e and well r o u n d e d , with 13 axial rings and nine pleural ribs.
Family Aulacopleuridae T h o m a s and O w e n s ( 1 9 7 8 ) c o m b i n e d two trilobite families,
Synphoria
stemmata
stemmata
(Clarke,
1900)
Figure
5.3E
Aulacopleuridae and O t a r i o n i d a e , into o n e family, Aulacopleuri-
Lectotype N Y S M 4 3 7 2 ( L e s p e r a n c e and B o u r q u e , 1 9 7 1 ) Type
m e m b e r s of the subfamily Scharyiinae are reported from New
Oriskany/Glenerie F o r m a t i o n s , C o l u m b i a C o u n t y . T h e cephalon
York. T h e aulacopleurids are small trilobites with a forward-
large,
is
This
species
slightly convex,
is has
from seven
the
Lower
dae, with two subfamilies Aulacopleurinae and Scharyiinae. No
Devonian
is
species.
the
tapering glabella. T h e LI glabellar lobe is separated from the
anterior border, and has no genal spines. T h e pygidium is n o n -
crenulations
glabella by a groove. In m a n y respects, except for size, they resem-
spinose and bluntly r o u n d e d , with 13 axial rings and nine pleural
ble proetids and are a m e m b e r of the order Proetida. T h o m a s and
ribs.
on
O w e n s did not a t t e m p t to reclassify the large n u m b e r of North A m e r i c a n species represented by this family, so most of the names
Synphoroides
dolphi
(Clarke,
1893)
Holotype NYSM 4317 Helderbergian at Port Jervis, O r a n g e County.
listed are traditional. Adrain and C h a t t e r t o n ( 1 9 9 5 ) revised the genera Harpidella and Maurotarion. Species referred to as Otarion in New York are in need of revision.
O R D E R
149
P R O E T I D A
Cyphaspis
sp.
Otarion? (Maurotarion)
Specimen B M S E - 1 1 0 3 5
coelebs
(Hall
and C l a r k e ,
1888)
Plastotype N Y S M 4 2 3 3
S t u m m ( 1 9 6 7 , Plate II, no. 2 1 ) illustrated a trilobite identified
Otarion . coelebs is a Lower Devonian trilobite from the Lower
as an Otarion? species. An articulated s p e c i m e n collected in the
Helderberg of Albany and S c h o h a r i e C o u n t i e s . T h i s is likely a
Middle Devonian Deep Run Shale in Livingston C o u n t y has
Maurotarion species (Adrain and C h a t t e r t o n
7
1995).
been identified as a Cyphaspis species ( J o n Adrain 1 9 9 9 , private communication).
Otarion? diadema (Hall and C l a r k e ,
1888)
Plastotype N Y S M 4 2 3 8 T h i s M i d d l e Devonian trilobite is f r o m " d e c o m p o s e d chert
Harpidella craspedota (Hall a n d C l a r k e , 1 8 8 8 ) Plate 1 2 8
boulders in the n e i g h b o r h o o d of C a n a n d a i g u a , New York" (Hall
Lectotype N Y S M 4 2 3 6 Harpidella from certain
craspedota
is a
small,
relatively c o m m o n
of layers the Centerfield
trilobite
L i m e s t o n e in
Middle
and Clarke
1888).
T h e s e b o u l d e r s , in
O n t a r i o C o u n t y , are
glacially t r a n s p o r t e d O n o n d a g a L i m e s t o n e .
Devonian Hamilton exposures in O n t a r i o and Livingston C o u n ties
in western New York.
S p e c i m e n s of Harpidella that
may
belong to this species have been collected from the M o u n t M a r i o n
Otarion? hudsonicum
(Ruedemann,
1901)
Holotype N Y S M 4 2 3 6
trilobite
T h i s trilobite is f r o m the O r d o v i c i a n , upper Utica Shale of
is characterized by long genal spines and 12 t h o r a c i c s e g m e n t s .
Green Island near Albany, Albany C o u n t y . It was assigned to a
Formation
and
the
Stafford
Limestone.
This
T h e r e is a short, axial spine on the fourth t h o r a c i c segment
new species because of the rarity of aulacopleurids in the Utica
and a long one on the sixth. Plate 128 shows a small cluster of
Shale.
specimens. Otarion? hybrida (Hall a n d C l a r k e , 1 8 8 8 ) Harpidella spinafrons ( W i l l i a m s in C o o p e r and W i l l i a m s , 1 9 3 5 ) Plates 129 and 130 Holotype U S N M 8 9 7 5 1 , s p e c i m e n U S N M 8 9 9 8 0 (labeled H . craspedota) T h i s species is f r o m the M i d d l e Devonian Tully F o r m a t i o n , West
Brook
Other
Member
specimens
are
near listed
Sherburne, as
Chenango
4 . 8 km
(3
miles)
County. south
of
Sherburne. T h i s trilobite has a d o u b l e row of anterior spines along the cephalic border, a juvenile characteristic retained in the holaspid. Plate 129 shows an entire but d a m a g e d s p e c i m e n . T h e base of the thoracic spine on the sixth segment is clearly shown. Plate 130 is of a well-preserved cephalon of the same species.
T h i s M i d d l e Devonian trilobite is f r o m " d e c o m p o s e d chert boulders in the n e i g h b o r h o o d of Canandaigua,'' O n t a r i o County. These boulders are glacially t r a n s p o r t e d O n o n d a g a L i m e s t o n e . Otarion? laevis ( H a l l , Otarion
7
1876)
laevis is k n o w n from o n e cephalon from the Upper
Devonian " C h e m u n g Formation", C h e m u n g County. Otarion? matutinum
(Ruedemann,
1901)
Syntypes N Y S M 4 2 4 1 t o 4 2 4 2 T h i s trilobite was identified f r o m material in Middle O r d o v i cian Trenton age pebbles within the Rysedorph C o n g l o m e r a t e , Rensselaer C o u n t y . Shaw ( 1 9 6 8 ) believed that O. matutinum and
Harpidella stephanophora (Hall a n d C l a r k e ,
1888)
Hypotypes N Y S M 4 2 5 3 t o 4 2 5 6 This Middle Devonian trilobite is from " d e c o m p o s e d chert boulders in the n e i g h b o r h o o d of C a n a n d a i g u a , New York" (Hall and Clarke
1 8 8 8 ) . T h e s e boulders are O n o n d a g a L i m e s t o n e
glacially transported into O n t a r i o County. Adrain and C h a t t e r t o n (1995)
Holotype N Y S M 4240
assigned
Cyphaspis
stephanophora
to
Harpidella.
O. hudsonicum might not be aulacopleurids because of the n o n separate nature of the basal lobes. Otarion?
(Maurotarion)
minuscula
(Hall,
1876)
Hypotypes N Y S M 4 2 4 3 t o 4 2 4 9 Otarion? minuscula is a trilobite of the S c h o h a r i e Grit, Albany C o u n t y , and O n o n d a g a L i m e s t o n e , O n t a r i o , Genesee, and Erie C o u n t i e s , which places it in the upper Lower Devonian or lower Middle D e v o n i a n . T h e s p e c i m e n illustrated in the work by Hall
Harpidella sp. Plate 131 T h e trilobite in Plate 131 is an as yet, undescribed species from
and Clarke ( 1 8 8 8 ) shows no evidence of the axial thoracic spine often found in this genus. T h i s is likely a Maurotarion (Adrain
the O n o n d a g a Limestone.
and C h a t t e r t o n 1 9 9 5 ) .
Maurotarion sp. Plate 132
Otarion? spinicaudatum
Specimens have been found in the Upper Silurian L o c k p o r t Group near Sodus, Wayne County. T h e y c a n n o t be identified with any known New York species.
(Shaw,
1968)
Holotype N Y S M 12243 Otarion spinicaudatum is from the Middle Ordovician, lower Middle Chazy beds and was identified from silicified specimens.
150
THE
It is considered to be o n e of the oldest m e m b e r s of this family.
Bathyurus
For l o c a t i o n s , see Shaw ( 1 9 6 8 ) .
Syntypes N Y S M 9 6 3 4 t o 9 6 3 6
taurifrons
(Dwight,
TRILOBITES
1884)
Bathyurus taurifrons is reported f r o m the Lower Ordovician Roachdale
Family Bathyuridae Bathyurid trilobites are f o u n d in the Lower and Middle Ordovician of New Y o r k — m o s t , if not all, below the middle Trenton. T h e y have a robust, nearly semicircular c e p h a l o n with stout genal spines.
T h e glabella
is
p r o m i n e n t and expands
forward or is parallel sided. Glabellar furrows are faint. T h e t h o r a x has 9 or 10 s e g m e n t s and no c o n s p i c u o u s pleural spines. T h e pygidium is nearly semicircular, s o m e t i m e s with an axial pygidal spine.
Acidiphorus
(Brett
and
Westrop,
1996)
of
the
Fort
Cassin
Formation,
Washington
County. O n e should refer to the original publication for the description.
platypus
(Fortey,
Dutchess
striata
(Whitfield,
1897)
T h i s species is f r o m the Lower Ordovician Fort Cassin Form a t i o n in V e r m o n t . In all probability it is also found in New York (Brett and Westrop 1 9 9 6 ) . seeiyi
(Whitfield,
1889)
species.
Bolbocephalus
seeiyi
is
a
trilobite
from
the
lower part of the Spellman F o r m a t i o n (Lower Ordovician, lower B e e k m a n t o w n G r o u p ) a t B e e k m a n t o w n , C l i n t o n County. T h e c e p h a l o n is convex, narrowing anterior to the occipital ring and t h e n e x p a n d i n g forward. T h e r e are no glabellar furrows. Grinnellaspis
Bathyurelhis
the W a p p i n g e r Valley in
Holotype A M N H 35823
Type
T h i s bathyurid is f r o m the Lower O r d o v i c i a n Scotia L i m e Member
in
Holotype A M N H 396
Holotype U S N M stone
Benthamaspis
Bolbocephalus
whittingtoni
Limestone
County.
cf.
G.
marginiata
(Billings,
1865)
L e c t o t y p e G S C 6 4 6 ( W h i t t i n g t o n 1953)
1979)
Brett and Westrop ( 1 9 9 6 ) tentatively identified specimens
Holotype GSC 56847 T h i s bathyurid is from the Lower O r d o v i c i a n Scotia L i m e s t o n e M e m b e r of the Fort Cassin F o r m a t i o n , W a s h i n g t o n C o u n t y . A
f r o m the Lower Ordovician Scotia L i m e s t o n e M e m b e r of the Fort Cassin F o r m a t i o n , Washington County, as this species.
c r a n i d i u m and two pygidia were j u d g e d identical to material from N e w f o u n d l a n d (Brett and Westrop 1 9 9 6 ) .
Raymondites
ingalli
(Raymond,
1913)
Holotype G S C 4328 Bathyurus cf.
B.
angelina
(Billings,
1859)
Holotype G S C 1084c, specimen M C Z 3790 T h e h o l o t y p e i s f r o m the Lower O r d o v i c i a n o f Q u e b e c . T h e M C Z s p e c i m e n was collected by C. D. Walcott in 1867 from a drift block near T r e n t o n Falls in either H e r k i m e r or O n e i d a County. T h i s species was identified by P. R a y m o n d in 1 9 0 5 .
Bathyurus extans (Hall,
1847)
Plate
133
Lectotype N Y S M 4 1 3 9 ( W h i t t i n g t o n 1 9 5 3 ) Type species. Bathyurus extans is a characteristic trilobite f r o m the Lowville L i m e s t o n e M e m b e r o f the Middle O r d o v i c i a n Black River G r o u p . It is f o u n d wherever these rocks are exposed in New York and is also reported from M i n n e s o t a . Plate 133 is a specim e n f r o m the Black River of Lewis C o u n t y .
Type species. Raymondites ingalli is a trilobite usually associated with the M i d d l e Ordovician Kirkfield F o r m a t i o n of O n t a r i o . Fisher ( 1 9 6 2 ) listed it as characteristic of the lower Trenton Larrabee L i m e s t o n e . D e M o t t ( 1 9 8 7 ) stated that he can only place the holotype in this species with certainty. All other specimens he is aware of are R. spiniger. Raymondites
longispinus
(Walcott,
1877)
Holotype M C Z 107237 The
holotype
of
this
Middle
Ordovician,
upper
Black
River/lower Trenton trilobite is from o n e of the quarries operated for building stone near Poland, H e r k i m e r County, in the m i d to late 1800s. Kay ( 1 9 5 3 ) listed R. longispinus from the lower Trenton
Rockland
(Napanee)
M e m b e r . T h e Raymondites genus
differs from Bathyurus in that it has o n e pair of lateral glabellar furrows rather than two, and the surface of the cephalon is
Bathyurus johnsoni
(Raymond,
1913)
pustulose.
Specimen U S N M A trilobite with this n a m e , but with no inventory n u m b e r , is in the U S N M and is listed f r o m the Lowville M e m b e r of the
Raymondites
spiniger
(Hall,
1847)
Holotype A M N H 854
Middle Ordovician Black River G r o u p , Utica, O n e i d a County.
D e M o t t ( 1 9 8 7 ) reported the h o l o t y p e as G S C 4 3 1 8 , stating it
T h e r e are no Black River rocks in the i m m e d i a t e Utica area, so
is the s p e c i m e n figured by Hall. Hall clearly stated that his figured
this is probably from the Lowville M e m b e r at N e w p o r t , H e r k i m e r
s p e c i m e n , and h o l o t y p e , is f r o m New York but did not give a spe-
C o u n t y , in an area on West C a n a d a C r e e k .
cific location o t h e r than the M o h a w k Valley. He did report
ORDER
151
PROETIDA
another similar specimen belonging to a M r . Logan f r o m M o n -
Cordania
treal, which Logan o b t a i n e d in C a n a d a . (Logan is Sir William
Lectotype N Y S M 4 2 1 0 ( W h i t t i n g t o n 1 9 6 0 )
Logan, the f i r s t director o f the Geological Survey o f C a n a d a . ) T h i s may be the G S C specimen. Raymondites spiniger is reported f r o m
becraftensis
Cordania
Clarke,
becraftensis
is
1900
from
the
Lower
Devonian
Glenerie
L i m e s t o n e , Becraft M o u n t a i n , H u d s o n , C o l u m b i a County.
the Middle Ordovician, upper Black River C h a u m o n t L i m e s t o n e and the lower Trenton R o c k l a n d (Napanee) L i m e s t o n e . G e o -
Cordania cyclurus (Hall a n d C l a r k e , 1 8 8 8 )
graphically it is widely distributed into O n t a r i o , Q u e b e c , Ken-
Lectotype N Y S M 4 2 1 5 (Whittington 1960)
tucky, and Illinois.
Cordania cyclurus is a trilobite of the Lower Devonian New Scotland L i m e s t o n e in Albany C o u n t y .
Strigigenalis cassinensis
(Whittington,
1953)
Holotype location u n k n o w n ; s p e c i m e n s N Y S M 1 5 3 8 4 t o 1 5 3 9 0 Brett and Westrop ( 1 9 9 6 ) described this species from the Lower Ordovician Scotia L i m e s t o n e M e m b e r of the Fort Cassin F o r m a t i o n , Washington County. Strigigenalis caudatus
(Billings,
(1913)
1865)
Strigigenalis
caudatus
reported
from
the
T h e holotype is from N e w f o u n d l a n d . brevispinum
(Raymond,
cian, upper Chazy G r o u p k n o w n only from a poorly preserved cephalon, cranidia, and pygidia. For locations, see Shaw ( 1 9 6 8 ) . Uromystrum brevispinum has a long un fur rowed glabella.
T h i s trilobite f r o m the M i d d l e D e v o n i a n H a m i l t o n shales, in
(Hall a n d C l a r k e ,
1888)
T h i s species is reported to be f r o m the Centerfield L i m e s t o n e in O n t a r i o C o u n t y . Mystrocephala varicella (Hall a n d C l a r k e ,
1888)
Lectotype N Y S M 4 2 2 3 ( W h i t t i n g t o n 1 9 6 0 ) varicella
is
from
the
Middle
Devonian
O n o n d a g a L i m e s t o n e in O n t a r i o C o u n t y .
Holotype C M H - 1 2 8 4 U,
1876)
O n t a r i o C o u n t y , is p r o b a b l y different f r o m A. gemmaea.
Mystrocephala
1905)
Uromystrum minor is similar to
(Hall,
Syntypes N Y S M 4 2 5 1 , 4 2 5 2
Uromystrum brevispinum is a trilobite of the M i d d l e O r d o v i -
minor ( R a y m o n d ,
ornata
Hypotype N Y S M 4 2 5 0
Mystrocephala ornata baccata
1905)
Lectotype C M H - 1 2 8 7 (Shaw 1 9 6 8 )
Uromystrum
Mystrocephala arenicolus is f o u n d in the u p p e r Lower Devon-
Mystrocephala
Lower Ordovician B e e k m a n t o w n at T i c o n d e r o g a , Essex C o u n t y .
Uromystrum
1888)
Plastotype N Y S M 4 2 0 6 ian S c h o h a r i e G r i t , S c h o h a r i e County.
Holotype G S C 6 3 5 Raymond
Mystrocephala arenicolus (Hall a n d C l a r k e ,
brevispinum b u t is k n o w n
only from cranidia and pygidia. It is from the M i d d l e O r d o v i c i a n , middle Chazy G r o u p . T h e U. minor differs in that it has a low,
Radnoria sp. Plate 135 T h i s trilobite was formerly referred to as Proetus stokesii. It is
indistinct glabella. For locations, see Shaw ( 1 9 6 8 ) .
f o u n d in the Lower Silurian R o c h e s t e r Shale. T h e specimen
Family Brachymetopidae
described ( J o n Adrain 2 0 0 0 , private c o m m u n i c a t i o n ) .
in Plate 135 is f r o m O r l e a n s C o u n t y . T h i s trilobite is being
Brachymetopids are small trilobites in the Lower Silurian and Devonian in New York. T h e c e p h a l o n is nearly semicircular in
Family Dimeropygidae
outline, with genal spines with a distinct border. T h e glabella is
O n l y o n e representative of this family is k n o w n in New York.
short and tapers forward. T h e basal glabellar lobes ( L I ) stand
T h e s e small trilobites, 1 cm or less in length, are mostly k n o w n
alone, being cut o f f by glabellar furrow S I . T h e t h o r a x has 10 seg-
from
ments. T h e pygidium is semicircular with n u m e r o u s axial rings.
c e p h a l o n is convex and pustulose. T h e t h o r a x has eight segments.
T h e pygidiual margin may be s m o o t h or spined. T h e entire dorsal
T h e pygidium is convex with three to six s e g m e n t s . W h o l e , arti-
surface of the trilobite is covered with tubercles.
culated s p e c i m e n s are very rare
silicified
remains
etched
from
limestone
in eastern
blocks.
The
N o r t h America,
probably because they inhabited shallower, high-energy environAustralosutura gemmaea
(Hall,
1876)
Plate
134
Lectotype N Y S M 4 2 1 7 ( S t u m m 1 9 6 7 )
m e n t s where preservation is poor. F o r this s a m e reason they, would be difficult to find unless silicified.
This species is found in the Jaycox, D e e p R u n , K a s h o n g , and W i n d o m Shales. T h e illustrated s p e c i m e n , in Plate 134 is f r o m
Dimeropyge
Livingston County. S p e c i m e n s reported from the O n o n d a g a are
H o l o t y p e N Y S M 12357
an undescribed species. T h e genus assignment is f r o m an abstract (Scatterday 1 9 8 6 ) .
clintonensis
Dimeropyge
clintonensis
(Shaw, is
a
1968) small
trilobite
of
the
Middle
O r d o v i c i a n , middle Chazy and the only representative of the
152
THE
family in New York. For locations, see Shaw ( 1 9 6 8 ) . It is k n o w n
Coniproetus
f r o m silicified maraspids a n d holaspids. T h e c e p h a l o n has long
Lectotype A M N H 3 9 3 2 1
genal spines, and the transitory pygidium has a p r o m i n e n t axial
4706
conradi
(Hall,
TRILOBITES
1861) (Lieberman
1 9 9 4 ) , hypotype N Y S M
spine f r o m the second axial ring. T h i s pygidial spine is apparently
T h e lectotype is f r o m the Lower Devonian Schoharie Grit
lost in the holaspis. Dimeropyge clintonensis closely resembles D.
in Albany County. T h e N Y S M specimen is from Glenerie For-
virginiensis, from W h i t t i n g t o n and Evitt ( 1 9 5 4 ) . No articulated
mation,
s p e c i m e n s of the New York species are k n o w n . An articulated
cephalic features are very similar to those of C. angustifrons. T h e
Dimeropyge specimen
pygidium is r o u n d e d and 1.8 times wide as long. T h e r e are 10
is k n o w n
from
the Trenton
of C a n a d a
(Ludvigsen 1 9 7 9 b ) .
Becraft
Mountain,
Hudson, Columbia
County. T h e
axial rings. T h e pleural furrows are faint and b e c o m e indistinct posteriorly. T h e r e is a border.
Family Proetidae Proetids existed over m o r e geologic t i m e than any other trilobite family. According to Fortey and O w e n s ( 1 9 9 7 ) the family
Coniproetus folliceps (Hall a n d C l a r k e ,
1888)
Plate
136
Lectotype N Y S M 4 7 2 2 ( L i e b e r m a n 1994)
arose in the Early O r d o v i c i a n and lasted until trilobites b e c a m e
T h i s species is from the M i d d l e Devonian, upper O n o n d a g a
extinct during the great Late P e r m i a n e x t i n c t i o n event ( a b o u t 2 5 0
L i m e s t o n e near LeRoy, Genesee County. T h e cephalon is semi-
million years a g o ) . T h e order Proetida has m e m b e r s f r o m the Late
circular in outline without genal spines. T h e r e is a narrow border.
C a m b r i a n . Proetids have a r o u n d e d , inflated glabella that tapers
T h e surface is covered with low, coarse granules. T h e occipital
forward. T h e y have a well-developed cephalic b o r d e r and usually
ring has a faint axial n o d e . T h e lateral occipital lobes are c o n -
m e d i u m - l e n g t h genal spines. T h e t h o r a c i c pleurae have r o u n d e d
nected posteriorly to the occipital ring. T h e r e are no axial t h o -
ends. T h e pygidium is semicircular and often has a border. T h e
racic n o d e s . T h e pygidium has at least 10 axial rings and eitht or
first New York species are f o u n d in the M i d d l e O r d o v i c i a n and
m o r e pleurae. T h e r e is a narrow border. T h e surface is granulose.
are u n d o u b t e d l y i m m i g r a n t s f r o m European trilobite p o p u l a -
Plate 136 illustrates the lectotype.
tions.
These
early
representatives
did
not
last
past
the
Silurian b u t were replaced by a n o t h e r wave of proetids in the
Cornuproetus
Early Devonian ( L i e b e r m a n 1 9 9 4 ) . T h e proetids are nowhere as
H o l o t y p e Y P M , hypotype Y P M 2 7 8 1 0
abundant
as
Isotelus,
Dalmanites,
and
phacopids
respective periods, b u t their presence
is
known
exuviae. W h o l e , articulated s p e c i m e n s are
beecheri
(Ruedemann,
1926)
from
their
T h i s trilobite is part of Beecher's collections from Beecher's
from
their
Trilobite Bed in the Upper Ordovician Frankfort Shales n o r t h
uncommon, both
of R o m e , O n e i d a C o u n t y , the best s p e c i m e n s of which are in
because of low p o p u l a t i o n s and because the exoskeleton was
Y P M . N o n e of the New York Ordovician proetids have been
not very robust. In the M i d d l e D e v o n i a n , however, there are l o c a -
redescribed.
tions in the Centerfield L i m e s t o n e in Livingston C o u n t y where
must be considered tentative.
groups of whole Pseudodechenella rowi have been f o u n d . In
T h e assignment to
Cornuproetus by Cisne
(1973)
1994
L i e b e r m a n revised the proetids o f the D e v o n i a n o f eastern N o r t h
Crassiproetus
A m e r i c a including those in New York. T h e Silurian and O r d o v i -
Specimens A M N H 39329, 39337, 44700, 44707 to 44713
cian proetids need s o m e a t t e n t i o n . T h e features of the described proetids from New York are in Table 5 . 8 .
brevispinus
(Fagerstrom,
1961)
F r o m the M i d d l e Devonian O n o n d a g a Limestone and its equivalent in O n t a r i o and western New York and Albany County, this species is k n o w n f r o m cranidia and pygidia. It differs from
Basidechenella?
hesionea
(Hall,
1861)
C.
Holotype A M N H 2898 This
Lower
crassimarginatus by having a narrow cephalic border and, a
glabella that is wider and semicircular in the dorsal anterior view.
Devonian
species
from
the
Schoharie
Grit,
S c h o h a r i e C o u n t y , is k n o w n from two pygidia. T h e pygidium is
T h e r e is a small m e d i a n occipital n o d e . T h e pygidium has 18 axial rings and 15 pleural s e g m e n t s .
semicircular, with 13 axial rings and nine pleural s e g m e n t s . T h e r e are no tubercles on the axial rings.
Crassiproetus
crassimarginatus
(Hall,
1843)
Lectotype A M N H 3 9 3 2 8 ( L i e b e r m a n 1994) Coniproetus
angustifrons
(Hall,
1861)
Lectotype A M N H 2 9 0 0 ( S t u m m 1 9 5 3 b )
T h e lectotype is from Williamsville, Erie County. T h i s proetid is widely distributed from the Middle Devonian O n o n d a g a Lime-
T h i s species is f r o m the Lower D e v o n i a n S c h o h a r i e Grit of
stone and age-equivalent rocks of New York, O n t a r i o , Michigan,
Albany County. Apparently it is only positively k n o w n from
O h i o , and Kentucky. S p e c i m e n s have been reported from the
cranidia. Pygidia assigned to this species by Hall and Clarke are
Lower Devonian S c h o h a r i e Grit in S c h o h a r i e C o u n t y and the
not accepted by o t h e r a u t h o r s . T h e species is distinguished by the
Middle
larger than usual sagittal width of the cephalic border. T h e r e is
T h e c e p h a l o n is semicircular and has a wide b o r d e r and no genal
no medial occipital n o d e .
spines. T h e glabellar outline in dorsal anterior view is parabolic
Devonian
Onondaga
Limestone
in
Genesee County.
Table 5.8. Features of the described proetids of New York NAME
AGE,
Cornuproetus
beecheri
(Ruedemann, 1926) Proetus
(Proetus)
clelandi
STRATA
U. Ord.. Frankfort Shale M. Ord., Chazy?
LATERAL OCCIPITAL LOBE
OCCIPITAL NODE
GENAL SPINES
THORACIC AXIAL NODES
PYGIDIAL AXIAL NODES
PYGIDIAL AXIAL RINGS
PYGIDIAL PLEURAL SEGMENTS
SEP
Yes
Yes
No
No
7
5
No
Yes
(Raymond, 1905) Proetus
Ord.
parviusculus
(Hall, 1860) Proetus spurlocki (Meek,
Ord.
1872) Proetus
undulostriatulus
(Hall, 1847) Hedstroemia
pachydermata
(Barrett.
['Jo.
M. Ord., Snake Hill Shale Sil., Decker Ferry Limestone
1b
1878) Proetus artiaxis (Howell
and Sanford, 1947) Proetus
tenuisulcatus
(Howell and Sanford, 1947)
U. Sil., Oak Orchard Dolostone U. Sil., Oak Orchard Dolostone
No SEP
No
No
3^ 7
Faint
13
9
hesionea
L. Dev., Schoharie Grit
angustifrons
L. Dev.. Schoharie Grit
Faint
No
Yes
No
7 or 8
5 or 6
conradi (Hall,
L. Dev., Glenerie Formation L. Dev., Schoharie Grit
Faint
No
Yes
No
10
4 or 5
No
14
12
No
13
10
No
8 or 9
4 Faint
10 or 11 10
8
Yes
Basidechenella
(Hall, 1861) Coniproetus
(Hall, 1861) Coniproetus
1861) Crassiproetus
schohariensis
(Lieberman, 1994) Crassiproetus
L. Dev., Schoharie Grit
stummi
(Lieberman, 1994) Gerastos protuberans (Hall,
1859) Proetus hesione (Hall, Basidechenella
1861)
canaliculata (Hall, 1861)
L. Dev., New Scotland Limestone L. Dev.. Schoharie Grit M. Dev., Onondaga Limestone
No
No
SEP
Faint
No
No
Table 5.8.
Continued
NAME
AGE,
Basidechenella clara (Hall, 1861) Coniproetus folliceps (Hall and Clarke, 1888) Crassiproetus brevispinus (Fagerstrom, 1961) Crassiproetus crassimarginatus (Hall, 1843) Crassiproetus neoturgitus (Lieberman, 1994) Monodechenella halli (Stumm, 1953) Proetus microgemma (Hall and Clarke, 1888) Pseudodechenella arkonensis (Stumm, 1953) Pseudodechenella rowi (Green, 1838) Dechenella haldemani (Hall, 1861) Monodechenella macrocephala (Hall, 1861) Proetus jejunus (Hall and Clarke, 1888) Proetus marginalis (Conrad, 1839)
M. Dev., Onondaga Limestone M. Dev., Onondaga Limestone M. Dev., Onondaga Limestone M. Dev., Onondaga Limestone
STRATA
M. Dev., Onondaga Limestone M. Dev., Onondaga Limestone M. Dev., Onondaga Limestone M. Dev., Hamilton Group M. Dev., Hamilton Group M. Dev., Hamilton Group M. Dev., Hamilton Group
LATERAL OCCIPITAL LOBE
OCCIPITAL NODE
GENAL SPINES
THORACIC AXIAL NODES
PYGIDIAL AXIAL NODES
PYGIDIAL AXIAL RINGS
PYGIDIAL PLEURAL SEGMENTS
SEP
No
Yes
No
No
11
4 or 5
CON
Faint
No
No
No
10
8
Faint
Yes
18
15
Mo
No?
No
16
14
No
13
10
Yes
9
9
Yes
11
7 or 8
No
SEP
Yes
Yes
Yes
Yes
13
9
SEP
Faint
Yes
No
No to faint
11
8
SEP
No
No
No
No to faint
17
10
SEP
No
Yes
Faint
Yes
14
VA
Yes
10
8
M. Dev., Hamilton Group M. Dev., Hamilton Group
SEP, separated by a groove from the occipital ring; CON. connected to occipital ring.
i lo
ORDER
PROETIDA
155
or subsemicircular. T h e r e are about 16 pygidial axial rings and
lar furrows are deeply incised. T h e r e is no median occipital node
about 14 pleural segments. T h e r e is a pygidial border.
and the lateral occipital lobes are c o n n e c t e d posteriorly to the occipital ring. T h e r e are no axial t h o r a c i c nodes. T h e pygidium
Crassiproetus
neoturgitus
(Lieberman,
has 17 axial rings and 12 pleural s e g m e n t s . T h e r e is a pygidial
1994)
border, which widens posteriorly. Plate 138 is a whole specimen
Holotype A M N H 4 4 7 2 0 This species was described using two exfoliated pygidia f r o m
from the U n i o n Springs M e m b e r o f the Marcellus.
the Middle Devonian O n o n d a g a L i m e s t o n e in S c h o h a r i e County. There are 13 axial rings and ten pleural segments. A pygidial
Decoroproetus corycoeus ( C o n r a d ,
border is present.
Lectotype A M N H 1 8 2 9 (Holloway 1 9 8 0 ) , hypotype N Y S M 4 7 0 7
1842)
Plates
139 and
140
Found in the lower R o c h e s t e r Shale and reported from the Crassiproetus
sehohariensis
(Lieberman,
1994)
L o c k p o r t l i m e s t o n e , this trilobite is suboval and has long genal
Holotype A M N H 4 4 6 9 9
spines reaching the sixth t h o r a c i c s e g m e n t . T h e eyes are large and
T h e holotype exfoliated pygidium is from the Lower D e v o n ian Schoharie Grit of O r a n g e C o u n t y . O t h e r pygidia assigned to
r e n i f o r m . Plate 140 shows the s a m e s p e c i m e n as Plate 139 but shows an
associated
ophiuroid
(brittlestar Furcaster echinatus).
this species are either from the S c h o h a r i e Grit or f r o m the Middle Devonian O n o n d a g a o f Albany and S c h o h a r i e C o u n t i e s . T h e r e
Gerastos
are 14 axial rings and 12 pleural segments. No pygidial b o r d e r is
Lectotype A M N H 3 5 2 3 9 ( L i e b e r m a n 1 9 9 4 )
evident on the illustrations in L i e b e r m a n ( 1 9 9 4 ) .
protuberans
(Hall,
1859)
T h e lectotype is a pygidium from the Lower Devonian New Scotland L i m e s t o n e . A partial c e p h a l o t h o r a x was also figured by
Crassiproetus
stummi
(Lieberman,
1994)
Hall ( 1 8 5 9 b ) . T h e pygidium has eight axial rings and f o u r or five
Holotype U M M P 2 9 5 1 9
pleural segments. Pygidia with this description are k n o w n from
T h i s species, k n o w n only from pygidia, is f o u n d in
the
O n o n d a g a Limestone and S c h o h a r i e Grit o f S c h o h a r i e County.
the O n o n d a g a o f O n t a r i o C o u n t y and the Bois Blanc F o r m a t i o n of Michigan.
T h e holotype is from the Bois Blanc F o r m a t i o n of M i c h i g a n . There are 13 axial rings and ten pleural s e g m e n t s . T h e r e are no axial nodes, and a pygidial b o r d e r is present.
Hedstroemia
pachydermata
(Barrett,
1878)
T h i s genus is widespread in n o r t h e r n Laurentia, Fngland, and Baltica. It was first reported in eastern North A m e r i c a as H.
Cyphoproetus cf.
C.
wilsonae ( S i n c l a i r )
Plate
137
pachydermata in the Deckers Ferry F o r m a t i o n in O r a n g e C o u n t y
Specimen PRI 4 9 6 3 3
and in New Jersey.
This small proetid is from the M i d d l e O r d o v i c i a n , lower Trenton G r o u p . T h e genus is characterized by the large LI lobes
Mannopyge
isolated by the SI furrow. A C a n a d i a n specimen figured by Lud-
Holotype A M N H 4074
halli
(Stumm,
1953)
vigsen ( 1 9 7 9 b , Figure 3 1 C ) differs slightly from the PRI trilobite.
Type species. T h e h o l o t y p e of this trilobite is an incomplete
Another characteristic listed by O w e n s ( 1 9 7 3 , p. 2 7 ) , lateral lobes
t h o r a x and c o m p l e t e pygidium from the E d g e d iff M e m b e r of the
on the occipital ring, is not shown on the Ludvigsen illustration
O n o n d a g a L i m e s t o n e , Williamsville, Erie C o u n t y . T h e pygidium
but can just be made out on the left side of the PRI s p e c i m e n in
is very distinctive. T h e r e are nine pygidial axial rings and nine
Plate 137. T h e C a n a d i a n specimen appears to have a n a r r o w
pleural s e g m e n t s . A groove across the distal end of the pleural
preglabellar field. This is not evident on the PR] trilobite. Cypho-
segments separates the distal parts into n o d e s . T h e s e nodes are
proetus is a Silurian genus s o m e w h a t different from this species.
rounded and appear as part of an u n f o r m e d border. No other
T h e s e differences are under
proetid f r o m New York has these characteristics. T h i s trilobite
investigation
( J o n Adrain
1999,
private c o m m u n i c a t i o n ) .
has also been reported f r o m O n t a r i o . T h e genus was erected by Ludvigsen ( 1 9 8 7 ) .
Dechenella
haldemani
(Hall,
1861)
Plate
138
Lectotype A M N H 5 5 0 4 ( L i e b e r m a n 1994) T h i s trilobite is restricted to the M i d d l e Devonian Marcellus
Monodechenella
macrocephala
(Hall,
1861)
Plate
141
Lectotype A M N H 4 7 3 4 ( L i e b e r m a n 1 9 9 4 )
F o r m a t i o n , lower Hamilton G r o u p . S p e c i m e n s have been f o u n d
Type species. T h e lectotype is f r o m O n t a r i o County. A proetid
in Otsego and O n o n d a g a C o u n t i e s . T h e illustration from Hall
of the M i d d l e Devonian H a m i l t o n G r o u p and its equivalents, M.
and Clarke ( 1 8 8 8 ) is of a specimen from Pennsylvania, which was
macrocephala is often f o u n d in the s a m e horizons with Pseudo-
clearly designated to be the h o l o t y p e . T h e selection of a lectotype
dechenella
may be invalid. T h e cephalon is semicircular in outline with short
However, in the Deep Run and Kashong Shales it is the most
genal spines. T h e cephalic b o r d e r is b r o a d , and there is a narrow
c o m m o n proetid. T h e c e p h a l o n is semicircular in outline with
preglabellar field. T h e glabella narrows anteriorly and the glabel-
short genal spines. T h e glabella is inflated and pustulose and in
rowi,
although
in
significantly
reduced
numbers.
THE
156 dorsal view extends anteriorly over the wide cephalic border. SI
Proetusparviusculus
is deeply incised and extends perpendicular toward the m e d i a n
S p e c i m e n A M N H 1071
line, with a sharp dog-leg b e n d posteromedially, nearly to S O . T h e
(Hall,
TRILOBITES
1860)
Proetus parviusculus is an
Upper O r d o v i c i a n , O h i o
proetid.
occipital ring is wide, with lateral lobes separated by a shallow
T h e s p e c i m e n m e n t i o n e d is from Floyd, O n e i d a County, near
groove. T h e r e is no m e d i a n occipital n o d e . T h e pygidium is
R o m e . B o t h Middle O r d o v i c i a n Utica and Upper Ordovician
longer than wide and has 14 axial rings and 12 pleural s e g m e n t s .
F r a n k f o r t Shales are exposed in the area. A specimen in the
T h e r e is a pygidial border. T h e entire test is covered with g r a n u -
USNM
lations, coarsest on the glabella.
O r d o v i c i a n ) Utica Shale, Holland Patent, O n e i d a County, and is
(USNM 34490)
is a
proetid
from
(probably Upper
part of the Rust collection. Proetus artiaxis (Howell and Sanford, 1 9 4 7 ) Proetus spurlocki (Meek,
Holotype U S N M 4 8 8 1 2 7 T h i s trilobite is k n o w n f r o m a single pygidium f o u n d in the Upper Silurian E r a m o s a M e m b e r o f the L o c k p o r t G r o u p . T h e
1872)
Specimen U S N M 92544 Proetus spurlocki is an
Ohio
Upper Ordovician
proetid.
It
pygidium has a narrow axial lobe, which is almost parallel sided.
is included here because of a small pygidium in the National
T h e axis is rather highly convex and has three well-defined seg-
M u s e u m from Floyd, O n e i d a C o u n t y , labeled with this n a m e (Hurlburt Collection).
ments in its a n t e r i o r halt.
Floyd
is a town northeast of R o m e ,
O n e i d a County. B o t h the Middle Ordovician Utica and Upper Proetus
(Proetus) clelandi
(Raymond,
O r d o v i c i a n Frankfort Shales are exposed in the area.
1905)
Lectotype C o r n e l l M u s e u m 5 6 7 8 a (Shaw 1 9 6 8 ) T h i s trilobite was part of the Jewett Collection purchased by Cornell University in 1868 (Shaw 1 9 6 8 ) . T h e description a c c o m panying the only k n o w n s p e c i m e n was " C h a z y L i m e s t o n e , Chazy Village, New York" in C l i n t o n County. I n a s m u c h as b o t h Chazy and Trenton L i m e s t o n e s are f o u n d in the area and since no o t h e r s p e c i m e n s have been f o u n d in the Chazy, the exact stratigraphic horizon is in d o u b t .
Proetus tenuisulcatus (Howell and Sanford,
1947)
Holotype U S N M 488134 T h i s trilobite is f r o m the Upper Silurian Eramosa M e m b e r of the L o c k p o r t G r o u p in M o n r o e County. T h e glabella is subtriangular and reaches all the way to the b r i m in front. T h e glabellar furrows are very faint. T h e fixed cheeks are narrow, and the posterolateral p o r t i o n s are n a r r o w and end in sharp points. T h e pygidium is moderately convex. T h e axis is narrow; it tapers only
Proetus jejunus (Hall and Clarke,
a little and rises well above the pleural lobes. T h e r e are seven well-
1888)
T h e species is k n o w n f r o m a single exfoliated pygidium from the M i d d l e D e v o n i a n " s a n d y shales" o f the H a m i l t o n G r o u p , Albany C o u n t y . T h e pygidium is wider than long and has ten axial rings and eight pleural s e g m e n t s . T h e r e are p r o m i n e n t axial nodes.
defined axial s e g m e n t s . T h e pleural lobes are s m o o t h , with only faint traces of ribs. Proetus
undulostriatulus
(Hall,
1847)
Holotype? A M N H 3 0 1 0 1 , plastoholotype N Y S M 9 8 5 5 Hall first described this proetid from the Middle Ordovician
Proetus marginalis
(Conrad,
Snake Hill Beds, Saratoga County. Additional specimens from the
1839)
s a m e area have been described as Cyphaspis. T h e Snake Hill Beds
Hypotypes N Y S M 4 7 5 2 , 4 7 5 3 T h i s proetid trilobite was f o u n d in a D e v o n i a n b o u l d e r near
are an eastern New York equivalent of the lower Utica Shale.
Ithaca, T o m p k i n s C o u n t y . " T h i s has a m u c h less p r o m i n e n t front
Proetid sp. Plate 142
than the rowi, a deeper groove between the eye and middle lobe,
Specimens U S N M , M C Z 111714
and the tubercle which nearly j o i n s the lower angle of the eye is
Small
unprepared, u n n u m b e r e d , and undescribed
Middle
m u c h s m a l l e r " ( C o n r a d 1 8 3 9 ) . Hall and Clarke ( 1 8 8 8 ) ascertained
O r d o v i c i a n proetids are in collections from the Walcott-Rust
that the b o u l d e r referred to was f r o m the M i d d l e Devonian Tully
Q u a r r y in the Rust L i m e s t o n e M e m b e r of the Trenton G r o u p in
f o r m a t i o n . A n u m b e r of o t h e r proetids had been assigned to the
H e r k i m e r C o u n t y . B o t h the M C Z and the U S N M have speci-
species, and
m e n s . Plate 142 shows a prepared specimen from the Walcott-
Hall
synonymized
them
all
with
Pseudodechenella
rowi. T h e location of the type is u n k n o w n . T h e hypotypes are
Rust Q u a r r y n o w in the M C Z .
from the Tully F o r m a t i o n near O v i d , Seneca County. Pseudodechenella Proetus microgemma (Hall and Clarke,
1888)
Syntype N Y S M 4 7 4 0 T h i s species is k n o w n f r o m two pygidia f r o m the M i d d l e
arkonensis
(Stumm,
1953)
Holotype U M M P 25541 This
trilobite
is
described
from
the
Middle
Devonian
H a m i l t o n age rocks o f southwestern O n t a r i o . Lieberman ( 1 9 9 4 )
D e v o n i a n O n o n d a g a L i m e s t o n e o f O n t a r i o C o u n t y . I t quite pos-
reported
sibly is not a proetid.
H a m i l t o n G r o u p in central New York. S t u m m described it as
this
species
from
the
Ludlowville
M e m b e r of the
ORDER
157
A S A P H I DA there is no trace of
has also been reported in M i c h i g a n . Plate 147 shows a cluster
glabellar furrows, the genal spines reach to the sixth or seventh
similar to Pseudodechenella rowi except that
of individuals from the Tully F o r m a t i o n , revealing s o m e m o r -
thoracic segment, and there is a distinct occipital n o d e . T h e r e are
phological differences f r o m those lower in the H a m i l t o n . Pillet
axial nodes on the t h o r a x , m o r e strongly expressed on the m o r e
( 1 9 7 2 ) erected the new genus Pseudodechenella, with P.
posterior segments. T h e pygidium has a p r o m i n e n t axial n o d e on
the type species. Basse ( 1 9 9 7 ) agreed with Pillet that the New
the most anterior axial ring and lacks t u b e r c u l a t u m . In addition,
World
the pygidium has 13 axial rings and nine pleural segments.
Europe.
Pseudodechenella
5.7 ORDER ASAPHIDA Family Asaphidae
canaliculata
(Hall,
1861)
Holotype A M N H 4 2 5 3 , specimen Y P M 3 3 7 7 3
"Basidechenella"
species
are
different
from
rowi as
those
from
3 3 7 7 3 t o this
Asaphids are the m o s t n u m e r o u s s p e c i m e n s represented in the
species. It is an exfoliated pygidium labeled as c o m i n g from
New York O r d o v i c i a n . Although s o m e may be suspect by syn-
C h e r r y Valley, Otsego County, and is tentatively assigned to the
onymy, this will not displace t h e m f r o m " t h e most n u m e r o u s "
O n o n d a g a . T h i s is the only specimen f r o m New York. T h e h o l o -
title. We have f o u n d a total of 41 asaphids listed from the Lower,
type is from the Jeftersonville Limestone at the Falls of the O h i o ,
Middle, and Late O r d o v i c i a n of New York. Asaphids have plank-
Lieberman
(1994)
assigned specimen Y P M
Kentucky. T h e anterior cephalic b o r d e r has a medial transverse
tic protaspids, which makes for easy and widespread dispersal.
groove that is raised on each side, giving the a p p e a r a n c e of two
T h e meraspids and early holaspids usually have long genal spines,
transverse ridges on the border. O n e must question the identity
which often carries through to the adult. W h e n m a t u r e , the
of Y P M 3 3 7 7 3 until m o r e i n f o r m a t i o n is available.
asaphids have a s m o o t h , robust, u n o r n a m e n t e d body, which is well suited for plowing through and feeding in the surface mud
Pseudodechenella clara (Hall, 1 8 6 1 ) Plate 143
and debris of the sea b o t t o m . T h e holaspid has eight t h o r a c i c seg-
Lectotype A M N H 3 9 3 2 6 ( S t u m m 1953)
ments. T h e cephalic s u t u r e s are opisthoparian. The cephalon and
This
trilobite
is
described
from
the
Middle
Devonian
O n o n d a g a Limestone at Stafford in Genesee C o u n t y . A good
pygidium are often similar in size and shape, an observation that led to the genus n a m e Isotelus.
specimen is also in the U S N M ( U S N M 2 5 8 8 4 ) . T h e species has a subconical,
faintly
constricted
glabella
with
faint
glabellar
T h e oldest asaphids in New York are found in the Lower Ordovician B e e k m a n t o w n G r o u p , a n d then m o r e or less are
furrows. T h e cephalic b o r d e r is wide, flat, or slightly concave a n d
f o u n d c o n t i n u o u s l y upward t h r o u g h the Chazy, Black River,
has a distinctive raised o u t e r margin. T h e occipital ring has no
T r e n t o n , and L o r r a i n e G r o u p s . Asaphids geographically are very
medial node and has lateral lobes separated by a shallow furrow.
widely distributed in eastern North A m e r i c a ; therefore, it is not
T h e pygidium has 11 axial rings. T h e illustrated (Plate 143) spec-
likely that any straightforward evolutionary sequences will be
imen is from the M o o r e h o u s e M e m b e r of the O n o n d a g a L i m e -
found within the state. T h e family Asaphidae does not go beyond
stone in the Honeoye Falls Quarry, M o n r o e County. T h i s trilobite
the O r d o v i c i a n .
is widely distributed in the O n o n d a g a of New York and ageequivalent rocks ot O n t a r i o , Michigan, O h i o , and Kentucky.
* Basilicas romingeri
(Walcott,
1877)
H o l o t y p e M C Z , hypotype N Y S M 1 2 9 1 8 Pseudodechenella rowi ( G r e e n , 1 8 3 8 ) Plates 1 4 4 , 1 4 5 , 1 4 6 , and 147
Basilicas
romingeri
specimens
from
the
Middle
Ordovician
Black River G r o u p , H e r k i m e r C o u n t y , are in the N Y S M as N Y S M
Plastotype N Y S M 4 7 5 0
1 2 9 1 8 ( h y p o t y p e ) and the U S N M a s U S N M 6 1 2 7 7 . T h e genus
Type species. T h i s trilobite is f o u n d t h r o u g h o u t the M i d d l e
Basilicas differs
Devonian H a m i l t o n G r o u p , with the exception of the deeper-
than wide.
water black shales of the group. It is the m o s t c o m m o n l y f o u n d
B.
from
DeMott
wisconsensis
with
Basiliella (1987)
in that the pygidium
is longer
s y n o n y m i z e d Basilicas romingeri and
Basiliella
barrandi.
proetid of New York, with n u m e r o u s s p e c i m e n s f o u n d from Erie C o u n t y to east of Livingston County. T h e cephalon is s e m i c i r c u -
Basilicus ulrichi ( C l a r k e ,
lar in outline with genal spines. T h e cephalic b o r d e r has a n a r r o w
Specimen U S N M 61278
raised edge. T h e r e is no preglabellar field. T h e glabella is vaulted
1894)
T h e U S N M s p e c i m e n is f r o m the M i d d l e O r d o v i c i a n , upper
and tapers slightly forward. Glabellar tubercles are faint to absent.
Black
T h e occipital ring has a very slight to absent medial n o d e . T h e
Herkimer County.
River
Limestone,
1.6 km
(1
mile)
north
of Poland,
lateral occipital lobes are separated by a groove. T h e r e are no axial nodes on the s m o o t h t h o r a x . T h e pygidium has 11 axial rings and
Basilicus? vetustus (Hall,
eight pleural segments. Plate 144 shows a small group of indi-
Type A M N H 6 1 3
viduals from the W i n d o m Shale in Erie C o u n t y and Plate 145 is of a P.
rowi together with
Bellacartwrightia
whitelcyi. T h e species
1847)
T h e type of this Middle Ordovician Black River trilobite is from " t h e c o m p a c t Birdseye L i m e s t o n e of the M o h a w k Valley." In
THE
158
TRILOBITES
the U S N M a similarly labeled pygidium ( U S N M 4 7 7 9 ) has at least
o n e . T h e axis of the pygidium is not as p r o m i n e n t as the illus-
14 axial rings.
tration f r o m the Treatise suggests, but the posterior end of it is a well-defined r o u n d e d node. Homotelus is considered a question-
Basilicus
(Basiliella)
whittingtoni
(Shaw,
able genus and m a y be assigned to Isotelus.
1968)
Holotype NYSM 12535 T h i s species, from the Middle O r d o v i c i a n Chazy L i m e s t o n e , is only k n o w n f r o m cranidia and pygidia but is u n q u e s t i o n a b l y Basilicus and possibly Basiliella. Shaw equated this trilobite with Asaphus
marginalis
(abandon).
The
illustration
of the
f o r m e r A.
by
Raymond
Hyboaspis depressa
(Raymond,
1925)
Lectotype M C Z 1 0 1 1 3 8 (Shaw 1968) O n l y the pygidium of this Middle Ordovician Chazy species is k n o w n . However, R a y m o n d ( 1 9 2 5 ) considered these pygidia
The
as fairly c o m m o n . T h e r e is s o m e question of whether it is an
pygidium has paired, r o u n d e d p r o j e c t i o n s . For location i n f o r m a -
asaphid or an illaenid. See Shaw ( 1 9 6 8 ) for location i n f o r m a t i o n .
(1905)
is a
reconstruction
marginatus.
tion, see Shaw ( 1 9 6 8 ) . Isoteloides angusticaudus Basiliella barrandi
(Hall,
1851)
(Raymond,
1905)
H o l o t y p e C M 1285 Shaw ( 1 9 6 8 ) referred to this Middle Ordovician Chazy trilo-
Specimen M C Z 1 0 0 9 4 8 Type species. S p e c i m e n s of B. barrandi in the M C Z are from
bite as "Isotelus sp." because of its close similarity to Isotelus harrisi
the Middle O r d o v i c i a n Black River L i m e s t o n e s near Poland and
and the fact that only the pygidium, which was the original
Newport, H e r k i m e r County. M e m b e r s of the genera Basiliella and
figured s p e c i m e n , can be f o u n d . An entire specimen later figured
Basilicas
of
by R a y m o n d ( 1 9 1 0 c ) is lost. T h e Isoteloides species has well-
the facial suture in front of glabella" (Treatise). B o t h have genal
defined, flattened borders on the cephalon and pygidium. See
spines, a cephalic b o r d e r with a convex r i m , and a concave, well-
Shaw ( 1 9 6 8 ) for location i n f o r m a t i o n .
are
the
only
asaphids
"with
marginal
position
defined b o r d e r on the pygidium. Basiliella barrandi has a near Isoteloides canalis ( W h i t f i e l d , 1 8 8 6 ) Plate 149
semicircular pygidium. See also D e M o t t ( 1 9 8 7 ) .
L e c t o t y p e A M N H 3 5 2 7 6 (Brett and Westrop 1 9 9 6 ) Bellefontia
gyracanthus
(Raymond,
T h e species is from the Lower Ordovician Scotia Limestone
1910)
M e m b e r of the Fort Cassin F o r m a t i o n in Washington County.
Lectotype? ( W e s t r o p , K n o x , and Landing 1 9 9 3 ) Westrop et al. listed the family for genus Bellefontia from
T h e diagnosis from Brett and Westrop is "a species of Isoteloides
Lower O r d o v i c i a n as u n c e r t a i n . T h e Treatise placed it with the
with a relatively short axis that occupies up to about 80 percent
asaphids.
labeled Asaphus
of pygidial length a n d , consequently, relatively long border. Ante-
gyracanthus from Tribes Hill, C a n a j o h a r i e , M o n t g o m e r y C o u n t y .
rior b r a n c h e s of facial sutures are moderately divergent, so that
T h e r e are
specimens
in
the
MCZ
m a x i m u m frontal area width is equal to, or slightly greater than
T h e y are M C Z 3 4 7 8 and 3 4 7 9 .
glabellar length." T h e n a m e is u n f o r t u n a t e . T h e first record of ? Ectenaspis homalonotoides ( W a l c o t t ,
1877)
Plate
Asaphus canalis is in Hall's publication ( 1 8 4 7 ) . It is attributed to
148
C o n r a d and refers to material from the Chazy group. Whitfield
Syntypes F M N H 1 2 3 2 4 a , 1 2 3 4 1 b Walcott
( 1 8 8 6 b ) used the n a m e to refer to material from the Fort Cassin
based on s p e c i m e n s from Illinois, was said by R a y m o n d and
F o r m a t i o n . Later authors a b a n d o n e d the n a m e Isotelus canalis for
Narraway ( 1 9 1 0 ) to be fairly c o m m o n in the Middle O r d o v i c i a n
the Chazy material because of p o o r definition of the type speci-
Black River L i m e s t o n e s at Pattersonville, S c h e n e c t a d y C o u n t y .
m e n s . T h u s , o n e might argue that Isoteloides whitfieldi is now the
Later, R a y m o n d ( 1 9 2 5 ) withdrew this identification of the Black
proper n a m e .
?
Ectenaspis
homalonotoides,
originally
described
by
River specimens and equated the original with O n t a r i o material from just above the base of the T r e n t o n . T h i s later publication
Isoteloides peri (Fortey,
also
Holotype G S C 56799
assigned
it
to
his
new genus
Ectenaspis.
Ectenaspis
homa-
1979)
lonotoides has a long, tapering p r o j e c t i o n to the front of the
T h i s species is differentiated from /. canalis by a relatively
cephalon and a triangular pygidium. Plate 148 illustrates a spec-
longer pygidial axis, 85 to 9 0 % of the pygidial length. T h e species
imen
is f r o m the Lower Ordovician Scotia Limestone m e m b e r of the
from
Ontario
identified
as
Isoteloides
homalonotoides.
See
also D e M o t t ( 1 9 8 7 ) .
Fort Cassin F o r m a t i o n , Washington County. T h e species is also reported
Homotelus stegops
(Green,
1832)
from
Newfoundland
and
Pennsylvania
(Brett
and
Westrop 1 9 9 6 ) .
Hypotypes N Y S M 9 7 5 7 t o 9 7 6 5 T h i s trilobite is f o u n d in the U p p e r O r d o v i c i a n W h e t s t o n e
Isotelus
G u l f Shale o f the Lorraine G r o u p , O n e i d a C o u n t y . T h e cephalon
T h e genus Isotelus has not been properly revised, and species
has no trace of a border, and the pygidium has a poorly defined
identification, particularly in older m u s e u m specimens, can be
ORDER
159
A S A P H I DA
poor. Rudkin and Tripp ( 1 9 8 5 , 1 9 8 7 ) of the R O M have d o n e sig-
O n t a r i o retains its spines longer (i.e., at larger sizes) than those
nificant work with the Trenton and Upper Ordovician Isotelus
of the M o h a w k Valley. Plate 150 shows the neotype from the
species that o c c u r in O n t a r i o . Generally speaking, 7. platycephalus
W a l c o t t - R u s t Q u a r r y and is in the M C Z . Plate 151 is of a large,
is found in the Black River age rocks; /. gigas and /. walcotii,
near-perfect s p e c i m e n f r o m the s a m e location as the neotype.
in the middle Trenton; /. lotus and a n o t h e r isotelid informally
Plate 152 shows a cluster f r o m Trenton Falls. Plate 153 is the
known as "/. mafritzae" are found in the upper Trenton and lower
ventral view of a s p e c i m e n from Q u e b e c .
Upper O r d o v i c i a n ; and /. brachycephalus a n d I. maximus, in t h e Upper Ordovician. O t h e r u n n a m e d species have been identified,
Isotelus harrisi ( R a y m o n d ,
but similar careful e x a m i n a t i o n on the New York species has not
Lectotype Y P M 2 3 2 9 7 (Shaw 1 9 6 8 )
1905)
been done. Mature specimens of /. platycephalus, I. gigas, a n d /.
Isotelus harrisi is a fairly c o m m o n asaphid in s o m e Middle
latus do not have genal spines. Genal spines are f o u n d on m a t u r e
O r d o v i c i a n Chazy exposures. See Shaw ( 1 9 6 8 ) for location infor-
specimens
m a t i o n . It is a large trilobite b u t no articulated specimens are
of
/.
walcotti,
"I.
mafritzae?
I.
brachycephalus,
and
I. maximus. Although "/.
mafritzae" is not a formally published
name,
the
specimens
from
Lindsay
Formation
in
O n t a r i o are c o m m e r c i a l l y available with this n a m e and
Tripp
1985,
1987,
1989;
David
Rudkin
reported.
southern (Rudkin
1997,
private
communication).
Isotelus jacobus
(Clarke,
1894)
H o l o t y p e N Y S M 4 5 1 2 (lost) T h e type is listed f r o m C r o w n Point, Essex County. A large pygidium in the U S N M , U S N M 1 3 6 4 2 , is from this locality. It is
Isotelus annectans ( R a y m o n d ,
1920)
also listed from Middleville, H e r k i m e r C o u n t y , a Middle O r d o v i -
Holotype C M ?
cian, lower T r e n t o n area.
T h e holotype was originally described as Ectenaspis homalnotoiiles from New York but on further review was assigned to a new
Isotelus latus ( R a y m o n d , 1 9 1 3 )
species. R a y m o n d referred to this species as a link between Ecte-
Holotype GSC; specimens NYSM 17009, 17010
naspis and Isotelus. It is described as fairly c o m m o n in the Glens
T h e N Y S M s p e c i m e n s are f r o m M i d d l e O r d o v i c i a n , upper
Falls M e m b e r of the Middle Ordovician Trenton G r o u p at Pat-
Black River or lower T r e n t o n areas at Middleville and N e w p o r t ,
tersonville, Schenectady C o u n t y , and S m i t h s Basin, Washington
H e r k i m e r C o u n t y , respectively. O n e is a very large semicircular
County. T h e borders on the c e p h a l o n and pygidium are poorly
pygidium, 120 mm wide by 90 mm long. Given that /. latus is from
defined. Both the cephalic and pygidial axes are wide and poorly
higher up in the T r e n t o n / U p p e r O r d o v i c i a n , these s p e c i m e n s are
defined.
most
Isotelus giganteus ( R a y m o n d ,
1931)
platycephalus.
Isotelus cf. /. maximus ( L o c k e , 1 8 3 8 ) Plates 154, 1 5 5 , 1 5 6 ,
Holotype M C Z 1 0 4 9 8 2 T h e holotype, and only s p e c i m e n , is a
likely /.
and 157 huge h y p o s t o m e
Hypotypes N Y S M 4 3 1 3 , 4 3 1 5
from the upper Chazy Limestone at Tiger Point, Valcour Island,
R u e d e m a n n ( 1 9 0 1 ) f o u n d material in the Middle Ordovician
Clinton County. T h e h y p o s t o m e measures 8 0 m m across the pos-
Rysedorph C o n g l o m e r a t e , Rensselaer C o u n t y , that he assigned
terior points and about 100 mm at its widest. F r o m the size of the
to the U p p e r O r d o v i c i a n trilobite, f o u n d in O h i o and O n t a r i o .
hypostome and by knowledge of the relative size of the h y p o s t o m a
N Y S M 4 3 1 3 is a small, negative m o l d , which is not diagnostic.
of other species of the genus, R a y m o n d believed this s p e c i m e n was
On the s a m e m a t r i x are two pygidia and a c r a n i d i u m of a ptery-
6 0 0 to 6 7 5 mm ( 2 4 to 26 inches) long, m a k i n g it a truly giant trilo-
g o m e t o p i d . He believed the asaphid resembled /. maximus from
bite. It is not, however, likely to be a distinct species but a large
O h i o , which has a cephalon and pygidium with a very rounded
specimen of the large asaphids already k n o w n in the Chazy.
outline. T h e genal spines on O h i o s p e c i m e n s are long and thin. T h e y are kept through maturity. T h e New York s p e c i m e n s are
Isotelus gigas (DeKay, 1 8 2 4 ) Plates 1 5 0 , 1 5 1 , 1 5 2 , a n d 153
a q u e s t i o n a b l e a s s i g n m e n t . Plate 154 illustrates a specimen of
Neotype M C Z 1 0 0 9 3 8 (Rudkin and Tripp 1 9 8 9 )
/. maximus from O h i o and Plates 155 and 156 are the ventral
Type species. Isotelus gigas is a very well-known New York
view of a pyritized s p e c i m e n f r o m O h i o , with the posterior
trilobite because o f the n u m b e r s o f s p e c i m e n s , which were f o u n d
appendages possibly pyritized. Plate 157 is of a molt with the
in the Middle O r d o v i c i a n , middle Trenton Limestones of the
cephalon o v e r t u r n e d .
Trenton Falls area, H e r k i m e r County. I m m a t u r e holaspids have genal spines. T h e s e spines disappear as the trilobite grows,
Isotelus platycephalus
b e c o m i n g shorter with each successive molt. T h e size at which
Lectotype B M ( D a r b y and S t u m m 1965)
the genal spines disappear is different for /. gigas f r o m different localities. F o r example, /. gigas from the Lake S i m c o e area of
(Stokes,
1824)
T h e lectotype is from the Black River G r o u p of O n t a r i o and is f o u n d
in association with Basiliella barrandei and Bumastoides
160
THE
TRILOBITES
milleri. It differs f r o m /. gigas in that b o t h the cephalon and the
established that P.
pygidium are m o r e rounded and less triangular in outline. Black
L i m e s t o n e m e m b e r o f the t o p m o s t Middle Ordovician Trenton
River Isotelus species should be c o m p a r e d to /. platycephalus when
and in the base of the overlying shale. T h i s work also established
o n e is considering their validity.
the fact that P.
latimarginatus can be found in the Hillier
latimarginatus and P.
canadensis are the same,
and P. canadensis was a b a n d o n e d as a species. Both the cephalon Isotelus pulaskiensis
(Ulrich,
1926)
and pygidium have well-defined borders. T h e r e are short genal
Hypotype N Y S M 9 7 6 7
spines. T h e pygidium has n u m e r o u s , p r o m i n e n t pleurae that
T h e type of this species is f r o m Pennsylvania. T h e s p e c i m e n i n the U S N M , U S N M 2 3 6 2 8 , bearing this n a m e i s f r o m the
almost reach the margin. Plate 159 is a N Y S M specimen from Oneida County.
Pulaski drift ( U p p e r O r d o v i c i a n ) in the T r e n t o n Falls, H e r k i m e r County, area and is f r o m the Rust collection in a 1886 purchase.
Vogdesia
A small free c h e e k has long genal spines, longer than what is seen
N e o t y p e N Y S M 1 2 5 3 8 (Shaw 1968)
on i m m a t u r e /. gigas s p e c i m e n s .
bearsi
(Raymond,
1905)
Type species. T h i s trilobite is k n o w n from o n e area of the M i d d l e O r d o v i c i a n Chazy where it is considered abundant, Sloop
Isotelus simplex ( R a y m o n d a n d Narraway,
1910)
Bay, Valcour Island, C l i n t o n County. Strangely e n o u g h , similar
H o l o t y p e C M 1441
age exposures a short distance away do not yield this trilobite.
D e M o t t ( 1 9 8 7 ) listed this M i d d l e O r d o v i c i a n B l a c k River
T h e eyes are on short stalks. T h e pygidium has a concave border,
trilobite, originally described f r o m Pennsylvania, as f r o m Buck's
and the pleural field is flat. T h e t h o r a x , d o u b l u r e , and h y p o s t o m e
Q u a r r y near Poland, H e r k i m e r C o u n t y . It differs f r o m /. gigas
of V. bearsi are u n k n o w n .
in that the shields are less triangular and lack concave borders. S o m e asaphids f r o m the Black River Buck's Q u a r r y near Poland,
Vogdesia? obtusus
H e r k i m e r C o u n t y , bear the label /. iowensis ( M C Z 4 2 6 ) . T h e s e are
Neotype N Y S M 1 2 5 2 4 (Shaw 1968)
probably s p e c i m e n s of /. simplex.
(Hall,
1847)
T h i s fairly c o m m o n trilobite is f o u n d t h r o u g h o u t areas of the Middle Ordovician Chazy. T h e fragmentary nature o f most o f the
Isotelus walcotti U l r i c h , in ( W a l c o t t , 1 9 1 8 ) P l a t e 158
material prevents a m o r e exact placement within the asaphids.
Lectotype U S N M 6 1 2 6 1 a ( R u d k i n and Tripp 1 9 8 9 )
Additional s p e c i m e n s are M C Z 3 6 0 1 through 3 6 0 9 . R a y m o n d
Isotelus walcotti is f r o m the W a l c o t t - R u s t Q u a r r y , the source of all the s p e c i m e n s k n o w n to us. T h e q u a r r y is located in the
( 1 9 2 5 , p. 9 0 ) also reported this species f r o m V e r m o n t and Virginia. See Shaw ( 1 9 6 8 ) for location i n f o r m a t i o n .
lower Rust L i m e s t o n e o f the M i d d l e O r d o v i c i a n T r e n t o n G r o u p , H e r k i m e r C o u n t y . T h e lectotype is figured in Plate 158. T h e trilo-
Family Idahoiidae
bite bears a strong r e s e m b l a n c e to /. iowensis f r o m the Upper
Saratogia
O r d o v i c i a n of the n o r t h - c e n t r a l United States. T h e species differs
L e c t o t y p e U S N M 5 8 5 5 5 (Ludvigsen and Westrop 1983)
from the /. gigas f o u n d in the s a m e rocks in that it keeps its genal
Upper C a m b r i a n , Hoyt L i m e s t o n e , Saratoga County.
(Saratogia)
calcifera
(Walcott,
1879)
Plate
175B
spines t h r o u g h o u t its growth, and the a n t e r i o r and posterior ends of the c e p h a l o n and pygidium, respectively, are r o u n d e d in /.
Family Pterocephaliidae
walcotti while they have a m o r e p o i n t e d a p p e a r a n c e in /. gigas.
Cameraspis
Larger s p e c i m e n s of /. walcotti are rare. O n l y o n e a p p r o a c h i n g the
Specimens NYSM 14159, 14160
size of a m a t u r e /. gigas is in the M C Z , M C Z 4 2 2 , a n d it still has its genal spines.
convexa
(Whitfield,
1878)
Upper C a m b r i a n , Galway F o r m a t i o n , Saratoga County. See Ludvigsen and Westrop ( 1 9 8 3 ) for synonymies. T h i s species is also f o u n d in W i s c o n s i n , M i n n e s o t a , Pennsylvania, O k l a h o m a ,
Nileoides perkinsi
(Raymond,
1910)
M i s s o u r i , M o n t a n a , and W y o m i n g .
Lectotype U V M 2 - 6 6 (Shaw 1 9 6 8 ) Nileoides perkinsi is from the M i d d l e O r d o v i c i a n , upper Chazy of V e r m o n t . R a y m o n d ( 1 9 2 5 , p. 9 7 ) stated that he f o u n d a specimen from the Chazy o f C l i n t o n C o u n t y .
Cameraspis
sp.
Specimen M C Z 4810 Potsdam S a n d s t o n e , north edge of Battle Hill, near Fort A n n , W a s h i n g t o n County.
Pseudogygites
latimarginatus
(Hall,
1847)
Plate
159
Family Ptychaspididae
H o l o t y p e A M N H 1070 Hall described this species f r o m two isolated pygidia from an unspecified location near W a t e r t o w n , Jefferson C o u n t y . A similar species f r o m C a n a d a , f o u n d in a b u n d a n c e in the upper Middle Ordovician,
was
named
Pseudogygites
canadensis.
Fieldwork
Conaspis
whitehallensis
(Walcott,
1912)
Holotype U S N M 58579 Upper C a m b r i a n , Potsdam S a n d s t o n e , Whitehall, Washington County.
ORDER
A S A P H I DA
161
Idiomesus sp. (Bird and Rasetti, 1 9 6 8 )
Apatokephaloides sp.
Upper C a m b r i a n trilobite from a limited exposure in the East
(Bird
and
Rasetti,
1968)
An Upper C a m b r i a n species, f r o m C o l u m b i a County.
C h a t h a m quadrangle o f C o l u m b i a County. Hypodicranotus striatulus Keithiella
depressa
(Rasetti,
(Walcott,
1875)
Plates
160,
161,
a n d 162
1944)
Lectotype M C Z 1 0 0 9 8 6 ( R a y m o n d 1 9 2 5 )
Holotype G S C 71161 Upper C a m b r i a n , Hoyt L i m e s t o n e , Saratoga County. See Ludvigsen and Westrop ( 1 9 8 3 ) for synonymies. T h i s species is also found in Q u e b e c and N e w f o u n d l a n d .
Type
species.
Hypodicranotus striatulus
is
a
very
interesting
trilobite that was first described from the Middle Ordovician, upper T r e n t o n , W a l c o t t - R u s t Q u a r r y , H e r k i m e r County. In addition to the r e m o p l e u r i d c r a n i d i u m , the species has long genal spines r u n n i n g parallel to spinelike extensions of the occipital
Family Raphiophoridae All of the raphiophorids in New York are f o u n d in the Middle Ordovician. All are assigned to t h e genus Lonchodomas a n d are characterized by a glabellar m e d i o a n t e r i o r spine p r o j e c t i n g straightforward. T h e r e are also genal spines. T h e t h o r a x has five segments. T h e pygidium is small and semicircular and has a narrow border.
ring, giving the a p p e a r a n c e of a dual genal spine. T h e h y p o s t o m e is like no other. It is shaped like a tuning fork and extends to the e n d of the t h o r a x . T h e pygidium is very small. T h i s species has been reported f r o m New York, O n t a r i o , M i s s o u r i , Q u e b e c , and the District of M a c k e n z i e , C a n a d a . Plate 160 shows a specimen from the W a l c o t t - R u s t Q u a r r y . Plate 161 is of a n o t h e r specimen f r o m the W a l c o t t - R u s t Q u a r r y that split longitudinally, showing the long h y p o s t o m e . Plate 162 shows the small pygidium and
Lonchodomas
chaziensis
(Shaw,
the unusual, bifurcate lateral genal area. T h e genus has been
1968)
f o u n d in M i n n e s o t a , W i s c o n s i n , O k l a h o m a , Nevada, S c o t l a n d ,
Holotype N Y S M 12265 a
the central Ural M o u n t a i n s , and far n o r t h e a s t e r n Russia (see Lud-
long, four-sided glabellar spine projecting straight forward. It is
vigsen and C h a t t e r t o n 1 9 9 1 ) . Because of its shape it has been sug-
found in the Lower and Middle Chazy. See Shaw ( 1 9 6 8 ) for loca-
gested the trilobite might be pelagic, and its wide distribution
tion i n f o r m a t i o n .
goes along with this.
Lonchodomas
Lonchodomas
chaziensis
halli
is
a
(Billings,
trinucleoid
characterized
by
Remopleurides
1865)
In New York L. halli is f o u n d in the Upper Chazy. It is also found in Chazy age rocks in Virginia, Q u e b e c , and V e r m o n t . Shaw differentiated
the
two
Lonchodomas
species
from
the Chazy as follows: "L halli differs from L. chaziensis by p o s session of the following characters: ( 1 ) glabellar profile m o r e convex, with a m o r e definite keel present. ( 2 ) Glabellar furrows are extremely faint to absent. ( 3 ) Glabella tapers m o r e rapidly into glabellar spine, thus the glabella itself does not extend far beyond the fixed cheeks.
( 4 ) S-shaped genal spines.
(5)
Possession of a sight flat area on fixed cheek proximal to anterior portion of facial sutures." See Shaw ( 1 9 6 8 ) for location information.
Lonchodomas
(Billings,
1865)
H o l o t y p e G S C 1 7 6 0 (Shaw 1968)
Topotype N Y S M 1 2 2 7 9
(1968)
canadensis
Remopleurides
canadensis
is
found
throughout
the
Middle
O r d o v i c i a n Chazy. R e m o p l e u r i d s have a distinctive c r a n i d i u m , which can not easily be mistaken for any o t h e r genus. See Shaw ( 1 9 6 8 ) for location i n f o r m a t i o n . T h i s species is also reported f r o m Ottawa and Virginia. Remopleurides
linguatus
(Ruedemann,
1901)
Hypotypes N Y S M 4 7 7 0 t o 4 7 7 4 M i d d l e O r d o v i c i a n Trenton age pebbles in the Rysedorph Conglomerate. Remopleurides
tumidus
(Ruedemann,
1901)
Holotype N Y S M 4 7 7 5 hastatus
(Ruedemann,
1901)
Syntypes N Y S M 4 1 2 8 t o 4 1 3 5 Lonchodomas hastatus was f o u n d in Trenton age pebbles in the Rysedorp Hill C o n g l o m e r a t e , Rensselaer County.
Family Remopleurididae
Middle O r d o v i c i a n Trenton age pebbles in the Rysedorph C o n g l o m e r a t e , Rensselaer C o u n t y . Richardsonella sp.
( B i r d a n d Rasetti,
1968)
Upper C a m b r i a n , C o l u m b i a C o u n t y . Robergiella
cf.
R.
brevilingua
(Fortey,
1980)
Remopleuridids are known from the Upper C a m b r i a n to the
Brett and Westrop ( 1 9 9 6 ) reported a c r a n i d i u m and free cheek
Middle Ordovician in New York. T h e y are not c o m m o n any-
very similar to those of this species f r o m the Lower Ordovician
where. T h e family is characterized by long curved eye lobes. All
Scotia
species have genal spines and small pygidia.
W a s h i n g t o n County.
Limestone
member
of
the
Fort
Cassin
Formation,
THE
162
Family Saukiidae Hoytaspis speciosa
TRILOBITES
in North America during the latter part of the Middle Ordovi-
(Walcott,
1879)
cian (early C a r a d o c ) , likely due to the closing of the Iapetus
Lectotype U S N M 5 8 5 6 3 (Resser 1 9 4 2 a )
O c e a n and associated changes in currents and distances that
Type species. T h i s species is k n o w n f r o m the U p p e r C a m b r i a n ,
allowed the pelagic larvae to reach North A m e r i c a . Shaw and
Hoyt L i m e s t o n e , Saratoga C o u n t y , and also the Potsdam S a n d -
Lesperance ( 1 9 9 4 ) argued that all the Cryptolithus species repre-
stone drift near Trenton Falls, H e r k i m e r C o u n t y ( M C Z 3 8 5 8 ) .
sented in New York are part of a long-lived interbreeding popu-
Prosaukia
considered " m o r p h s " of Cryptolithus tessellatus. Since these trilo-
lation and as such do not hold species rank but should be briarcliffensis
(Lochman,
1946)
H o l o t y p e Y P M 17391
bites are clearly separated by time and stratigraphy in New York,
Upper C a m b r i a n f r o m rocks in D u t c h e s s C o u n t y referred to
we c h o s e to c o n t i n u e to list t h e m as separate species. T h e mature Cryptolithus trilobites are eyeless, while the tretaspids have lateral
as " H o y t D o l o s t o n e . "
eye tubercles. B o t h are considered to be b e n t h i c , living and feeding by plowing through the soft b o t t o m and ingesting the
Prosaukia hartti (Walcott, 1 8 7 9 ) Plate 1 7 5 A
m i c r o f a u n a or organic detritus. All have a characteristic, radially
Holotype U S N M 5 8 5 7 1 Upper C a m b r i a n , Hoyt L i m e s t o n e , Saratoga County. T h i s
pitted, cephalic b r i m or fringe. T h e pits are considered to have a sensory f u n c t i o n , but they also strengthen the fringe significantly
species is also f o u n d in W i s c o n s i n .
over a s m o o t h surface. T h e b r i m is divided horizontally into an Prosaukia
tribulis (Walcott,
upper part of the dorsal cephalic exoskeleton and a lower p o r t i o n ,
1912)
which
Holotype U S N M 58578
c o m e s free, probably during ecdesys.
Because of this
l a m i n a r nature, the upper b r i m and lower b r i m are called lamel-
Upper C a m b r i a n , Hoyt L i m e s t o n e , Saratoga County.
lae. T h e lower lamella has the genal spines.
Family Symphysurinidae T h i s family, o n c e considered a subfamily of Asaphidae, is r e p -
Cryptolithus bellulus ( U l r i c h , 1 8 7 8 ) Figure 5 . 5 C , D and
resented by two species, and no general family description is
Plate 163
given. T h e family is not listed in v o l u m e 1 of Treatise (revised).
Holotype USNM 41876
Symphysurina
Ordovician trilobite f o u n d in both limestones and shales. In New
Cryptolithus bellulus geographically is a widely distributed Late convexa
(Cleland,
1900)
Holotype PRI 5072
York State it is f o u n d in the Lorraine G r o u p shales in Oneida
T h i s trilobite is f r o m the Tribes Hill F o r m a t i o n of the Lower Ordovician in M o n t g o m e r y County. T h e glabella is vaulted,
County.
Cryptolithus
bellulus
with
preserved
appendages
was
f o u n d along with the m o r e f a m o u s appendaged Triarthrus eatoni
longer than wide, and the palpebral lobes are a b o u t m i d p o i n t .
in the Frankfort Shales of Beecher's Trilobite Bed. All we know of
T h e pygidium is semicircular to p a r a b o l i c , r o u n d e d with a well-
the soft tissue a n a t o m y of the cryptolithids is from the
defined axis. Axial segments are defined but not p r o m i n e n t .
pyritized, partial s p e c i m e n s k n o w n from this site. Cryptolithus
Symphysurina convexa
is characterized by a
pitted
prosopon
13
or
bellulus is very similar to C. lorettensis with the exception that the
o r n a m e n t a t i o n on external surfaces. See Westrop, K n o x , and
pits in E, and I, are radially aligned in C. lorettensis and alternat-
Landing ( 1 9 9 3 ) .
ing in C. bellulus. T h e r e are also statistical differences in the pit c o u n t s of the c o n c e n t r i c rows, but this is not diagnostic with
Symphysurina cf. S. woosteri U l r i c h , in ( W a l c o t t , 1 9 2 4 )
small sample sizes. Because of the observed c o - o c c u r r e n c e of C.
Specimens N Y S M 15209, 15210
bellulus and C. lorettensis in C a n a d a , it is questionable that these
Type species. T h i s trilobite is from the Lower Ordovician Tribes Hill
F o r m a t i o n , M o n t g o m e r y County.
is based on
O n e m u s t go outside the state to observe Cryptolithus species
two pygidia with stout medial spines. M o r e material is necessary
through the time sequence between the middle Trenton and the
for positive identification.
It
are distinct species. In New York, however, there is no intermix.
See Westrop, K n o x , and Landing
L o r r a i n e . Plate 163 shows a specimen from the Upper Ordovician
(1993).
shales in O n e i d a County.
Family Trinucleidae
Cryptolithus lorettensis ( F o e r s t e , 1924) Figure 5.5A, E and
Hughes, I n g h a m , and Addison ( 1 9 7 5 ) reviewed and revised trinucleids. T h e trinucleids are represented in New York by five species tolithus
or
subspecies:
tessellalus,
C.
Tretaspis
lorettensis, and
reticulata, C.
T.
bellulus.
diademata, The
Cryp-
Plates 164 a n d 165 Holotype G S C 10790 T h i s trilobite is f o u n d in the upper Sugar River Limestone,
trinucleids
R a t h b u n M e m b e r , or its equivalent limestones in New York. It is
are a family originating in the S o u t h e r n Trilobite Province Z o n e
f o u n d near the top of the m e m b e r where it replaces C. tessellatus.
of W h i t t i n g t o n ( 1 9 6 6 ) in the lower Arenig. T h e y first appeared
In s o m e areas in O n e i d a C o u n t y there is a narrow horizon where
ORDER
163
P T Y C H O P A R I IDA
both may be found, but this is not c o m m o n . In each of the U S N M
selaer C o u n t y . It differs f r o m T. reticulata in that the rows of pits
and N Y S M ( E - 9 2 0 ) collections there is a b o x of m i x e d C. tessel-
are arranged radially (aligned) and not just c o n c e n t r i c as they are
latus and C.
in
lorettensis s p e c i m e n s labeled
f r o m Trenton Falls,
T.
reticulata.
H e r k i m e r County. In the M o h a w k Valley, C. tessellatus is f o u n d in the middle Sugar River L i m e s t o n e , but in the R a t h b u n or upper
Tretaspis reticulata
m e m b e r of the Sugar River, C. lorettensis is the only Cryptolithus
Hypotypes N Y S M 4 8 2 0 t o 4 8 2 2
species (Vere 1 9 7 2 ) . T h e p r i m a r y distinguishing feature of C. lorettensis versus C.
tessellatus is that C.
lorettensis has an addi-
Tretaspis
(Ruedemann,
reticulata
was
1901)
described
from
remains
in
Middle
O r d o v i c i a n Trenton age pebbles in the Rysedorph C o n g l o m e r a t e ,
tional row of pits, I,, anterior to the glabella and genal area. T h i s
Rensselaer C o u n t y . T h e genus Tretaspis differs from Cryptolithus
row of pits is not always c o m p l e t e in front of the glabella but
primarily
always extends farther toward the median line than with C. tes-
expanding glabella, b u t Tretaspis species have three pairs of dis-
sellatus. Additionally, on
large s p e c i m e n s of C.
lorettensis,
in
the
glabella.
Both
have
a
bulbous,
forward-
the
tinct glabellar furrows, which are absent in Cryptolithus. T h e r e
exterior, median genal area is reticulated, and this area is s m o o t h
are three rows of pits a n t e r i o r to the glabella. T h e surface of the
on large specimens of C. tessellatus.
glabella is pitted and reticulated. T h e r e is no occipital spine. T h e pygidium is small and widely triangular. T h e n u m b e r of thoracic
Cryptolithus tessellatus (Green,
1832)
Figure 5 . 5 B and Plates
segments is u n k n o w n for T. reticulata, but six may be expected
166 and 167
by analogy. F o r a m o r e c o m p l e t e discussion of the trinucleids of
Holotype lost, neotype M C Z 1 0 6 4 9 2 (Shaw and Lesperance 1 9 9 4 ) Type species. T h e Middle O r d o v i c i a n C.
tessellatus in New
N e w York, particularly Cryptolithus, see W h i t t i n g t o n ( 1 9 4 1 , 1 9 6 8 ) and Vere ( 1 9 7 2 ) .
York is considered an index fossil of the Sugar River L i m e s t o n e of the Trenton G r o u p because it apparently first appears in New York in this limestone and is rarely, if ever, f o u n d in the overlying limestones. It is c o m m o n in s o m e h o r i z o n s and locations in the Sugar River in O n e i d a C o u n t y but is not u n i f o r m l y distributed anywhere. Although small, this trilobite has a distinctive and robust cephalon. T h e glabella is vaulted and s m o o t h , with only two shallow pits anterior to the occipital ring for glabellar furrows. T h e cephalon is r o u n d e d in outline and about twice as long as wide, including the long genal spines. Cephala are f o u n d with and without genal spines. T h o s e without genal spines have lost the lower lamella. T h e occipital ring has a central spine extending backward over the first few t h o r a c i c s e g m e n t s . T h e most characteristic feature of the trilobite is the a n t e r i o r b r i m or fringe, which has u n i f o r m rows of pits following the curvature of the anterior edge. T h e s e pits, their n u m b e r , and a r r a n g e m e n t are m a j o r factors in distinguishing the various species. Pit rows E, and I| have a thickened area called a girder, seen o n l y on the ventral
surface,
that
separates
them.
Cryptolithus
tessellatus
5.8 ORDER PTYCHOPARIIDA T h i s o r d e r includes trilobites primarily o f the C a m b r i a n and O r d o v i c i a n . In New York these trilobites are only represented in these periods. T h i s diverse o r d e r does not have any easily recognized defining features. W i t h i n the individual Ordovician families, however, there are distinctive features.
Family Conocoryphidae Atops trilineatus ( E m m o n s ,
Type species. Lower C a m b r i a n . Conocoryphe
verrucosa
(Whitfield,
Upper
Cambrian,
Potsdam
Sandstone,
Ausable
Chasm,
Keesville, Essex C o u n t y .
Family Dokimocephalidae
are only three rows of pits ( E , , I,, I ) immediately a n t e r i o r to the
Sulcocephalus
genal area. T h e t h o r a x has six t h o r a c i c segments, and the pygid-
H o l o t y p e N Y S M 10511
ium is rounded, being m u c h broader than it is long. W h o l e speci-
1884)
Syntypes A M N H 0 0 0 2 8 0 , 0 3 5 9 7 8 - 0 3 5 9 8 3
differs from the other New York Cryptolithus species in that there 2
1846)
Plastotype N Y S M 4 2 0 4
saratogensis
(Resser,
1942)
Lower C a m b r i a n , Theresa F o r m a t i o n .
mens from New York are rare. Plate 166 shows an u n c o m m o n , whole specimen from the Sugar River F o r m a t i o n of H e r k i m e r
Family Elviniidae
County. Plate 167 is included because it is listed f r o m Trenton
Calocephalites cf.
Falls, an area not usually included as exposing the Sugar River
minimus (Kurtz,
1975)
Ludvigsen and Westrop ( 1 9 8 3 ) .
rocks. Tretaspis diademata
(Ruedemann,
1901)
Dellea? landingi (Ludvigsen a n d Westrop, 1 9 8 3 )
Holotype N Y S M 4 8 1 9 Tretaspis
C.
Upper C a m b r i a n , Galway F o r m a t i o n , Saratoga County. See
diademata
is
Holotype N Y S M 14138 known
from
one
specimen
in
the
Middle Ordovician part of the Rysedorph C o n g l o m e r a t e , Rens-
Upper
Cambrian,
Hoyt
L i m e s t o n e , Saratoga County.
Ludvigsen and Westrop ( 1 9 8 3 ) .
See
164
THE
TRILOBITES
FIGURE 5.5. Features of New York Cryptolithus. The s p e c i m e n s are all about the s a m e size. For scale, see the plates. A.
Cryptolithus lorettensis from the u p p e r Sugar River Formation of the Trenton G r o u p , Jefferson
County. Note the four rows of pits anterior to the c h e e k area (NYSM). B. Cryptolithus tessellatus from the lower Sugar River Formation of the Trenton G r o u p , Herkimer County. Note that there are three rows of pits anterior to the
c h e e k area (TEW collection).
C.
Cryptolithus bellulus from the
Pulaski
M e m b e r of the
Lorraine G r o u p ,
O n e i d a County. There are four rows of pits anterior to the c h e e k area in this s p e c i m e n . D. Cryptolithus bellulus from the Pulaski M e m b e r of the Lorraine G r o u p , Lewis County. There are four rows of pits anterior to the c h e e k area. The radial a l i g n m e n t of the pits in rows E, a n d I, are not quite the s a m e as in C. The s p e c i m e n s in C a n d D are internal m o l d s a n d not as clearly d e f i n e d as those in A a n d B. The n u m b e r i n g system for the pit rows in Cryptolithus are as follows: R,, R , R , . . . are d e s i g n a t i o n s for the radially a l i g n e d rows starting with the medial 2
3
row; E, is the first circumferal row from the front e d g e of the c e p h a l o n ; I,, l , l 2
3
d e s i g n a t e the circumferal rows
after E,.
Dellea
saratogensis
(Resser,
1942)
Elvinia granulata
Holotype N Y S M 10511
(Resser,
1942)
Holotype U S N M 108815
Upper C a m b r i a n , Galway F o r m a t i o n , Saratoga C o u n t y . See Ludvigsen and Westrop ( 1 9 8 3 ) .
Upper C a m b r i a n , Galway F o r m a t i o n . Saratoga County. See Ludvigsen and Westrop ( 1 9 8 3 ) . T h e holotype is f r o m Nevada. T h e species is also f o u n d in Utah and Indiana.
Drabia cf.
D.
curtoccipita
(Wilson,
1951)
Upper C a m b r i a n , Galway F o r m a t i o n , Saratoga C o u n t y . See Ludvigsen and Westrop ( 1 9 8 3 ) .
Family Glaphuridae Glaphurids are best k n o w n from the two genera in eastern N o r t h A m e r i c a . Long considered trilobites of the Middle Ordovi-
Drabia cf. D.
menusa ( W i l s o n ,
1951)
U p p e r C a m b r i a n , Galway F o r m a t i o n , Saratoga C o u n t y . See Ludvigsen and Westrop ( 1 9 8 3 ) .
cian Chazy Limestones, they are currently k n o w n to have a longer t i m e range (Shaw 1 9 6 8 ) . Glaphurids are smallish trilobites f o u n d in reef facies. T h e i r exoskeleton is subelliptical, tapering
ORDER
165
PTYCHOPARIIDA
from the large cephalon to the small semicircular pygidium. T h e
County. T h e M C Z material is two specimens from the Middle
surface is either very pustulose or spiny. T h e glabella is suboval
O r d o v i c i a n Trenton L i m e s t o n e o f Port Jackson, Clinton County.
and p r o m i n e n t .
T h e s p e c i m e n in Plate 1 6 9 C is from a negative of a metal replica o f the holotype.
Glaphurina lamottensis ( U l r i c h , 1 9 3 0 ) Plate 1 6 8 B Holotype U S N M 8 0 5 5 3 Type species. Shaw ( 1 9 6 8 ) considered G. lamottensis from the upper part of the Middle O r d o v i c i a n , in the lower and the lower part of the middle Chazy, to be a considerably different trilobite from G. pustulosus. T h e exoskeletal p r o s o p o n is widely spaced tubercles, c o m p a r e d to the spines on G. pustulosus, and there are 12 thoracic segments instead of the 10 in G. pustulosus. Glaphurus pustulosus
(Walcott,
1877)
Plate
168A
Lectotype M C Z 7 5 6 6 B (Shaw 1 9 6 8 ) Glaphurus pustulosus is a trilobite of upper middle and basal upper Chazy G r o u p limestones. Disarticulated parts can be very abundant locally, but whole articulated s p e c i m e n s are rare. T h e o n e articulated and two partially articulated s p e c i m e n s reported by Shaw exhibit spines radiating f r o m the front of the cephalon,
Eoharpes
pustulosus
(Hall,
Eoharpes pustulosus is a
trilobite of the Middle Ordovician,
upper Black River G r o u p
in
the Watertown
area, Jefferson
County. Hibbertia valcourensis (Shaw,
1968)
Plate
169A, B
Holotype N Y S M 12293 Hibbertia
valcourensis
from
the
Middle
Ordovician,
from the Chazy by R a y m o n d ( 1 9 0 5 b , Eoharpes
ottawaensis
(both
1 9 1 0 b ) as Harpina anti-
quatus
and
(1859,
1865) f r o m C a n a d i a n s p e c i m e n s ) . T h e genus Hibbertia
described
S p e c i m e n N Y S M 12301
(Shaw,
1968)
T h i s trilobite is f r o m the M i d d l e O r d o v i c i a n , lower Chazy
specimen.
G r o u p . For location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
Family Harpidae
Scotoharpes cassinensis
(Whitfield,
1897)
Plate
Scotoharpes
cassinensis
is
a
Lower
Ordovician
reported from the B e e k m a n t o w n
of the cephalon, f o r m i n g a wide p l a t f o r m , t o o wide to call a genal
( 1 9 6 2 ) reported it also f r o m New York.
the trilobite. T h e fringe has a l a m i n a r structure that is separated into upper and lower lamellae by a suture a r o u n d the entire lateral edge. Separation is parallel to the plane of the fringe surface. During ecdysis the lamellae separate along this suture, and the trilobite crawls forward, leaving the m o l t e d exoskeleton behind. T h e eyes are small tubercles with two lenses each. T h e thorax has 12 to 29 segments. T h e pygidium is small with few segments. T h r e e of the six k n o w n harpids in New York are from the Middle Ordovician Chazy limestones. Dolichoharpes
sp.
(Shaw,
This trilobite is from the M i d d l e O r d o v i c i a n , middle and upper Chazy. D o l i c h o h a r p i d s have a narrower fringe that has three raised, serrated rows along the lateral edge of the upper fringe. For location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
Family Hystricuridae Hystricurids are o n l y f o u n d in the Lower O r d o v i c i a n in New York. T h e y are small pustulose trilobites with opisthoparian cephalic sutures. All have genal spines. Articulated s p e c i m e n s are u n k n o w n from New York. Hystricurus
conicus
(Billings,
1859)
Holotype GSC 516 Type species. T h e h o l o t y p e is f r o m the Lower Ordovician
Hystricurus
Plate
169C
crotalifrons
(Dwight,
1884)
Syntype N Y S M 9 7 6 6 F r o m the Lower O r d o v i c i a n Roachdale L i m e s t o n e , Dutchess County. Hystricurus
1865)
Fisher
Spellman F o r m a t i o n .
1968)
(Billings,
trilobite first
Group of Vermont.
B e e k m a n t o w n of Q u e b e c . It is also f r o m the Lower Ordovician
Specimens Y P M 2 3 2 9 4 , N Y S M 1 2 2 9 4 t o 1 2 3 0 0
Hibbertia ottawaensis
169D
Holotype U S N M 35817
wide fringe. T h e lateral fringe sweeps back posteriorly to the rear spine. T h i s genal platform extends close to the posterior end of
Billings
o r n a m e n t a t i o n . F o r location i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) . Hibbertia sp.
T h e cephalon is semicircular in the anterior p o r t i o n , with a very
by
differs f r o m Dolichoharpes in the width of the fringe area and the
of the pleura. T h e single articulated specimen is 3.5 mm long and
Harpids are nearly impossible to mistake for any o t h e r family.
lower
Chazy was described by Shaw from material previously described
the genal angle, the axis of the t h o r a c i c s e g m e n t s , and the ends could be a late meraspid. T h e r e are ten thoracic s e g m e n t s on this
1847)
Holotype A M N H 841
ellipticus
(Cleland,
1900)
H o l o t y p e PRI 5 0 7 3
Holotype G S C 3 2 9 , hypotype N Y S M 9 7 3 6 , s p e c i m e n M C Z 1 2 8 5 6
This species is k n o w n f r o m n u m e r o u s cranidia and pygidia
T h e holotype is from the Middle Ordovician of O n t a r i o . T h e
from the Lower O r d o v i c i a n Tribes Hill F o r m a t i o n , M o n t g o m e r y
N Y S M specimen is from the Snake Hill beds, Snake Hill, Saratoga
C o u n t y . See Westrop, K n o x , and Landing ( 1 9 9 3 ) .
166
THE
Hystricurus cf. H.
oculilunatus ( R o s s ,
TRILOBITES
Family Menomoniidae
1951)
Bolaspidella fisheri ( R a s e t t i , 1 9 6 7 )
S p e c i m e n s N Y S M 1 5 2 3 0 , 15231 Tribes Hill F o r m a t i o n , M o n t g o m e r y C o u n t y . See Westrop, K n o x , and Landing ( 1 9 9 3 ) .
Holotype U S N M 156682 M i d d l e C a m b r i a n , S t o c k p o r t Station, C o l u m b i a County. See Bird a n d Rasetti ( 1 9 6 8 , p. 2 6 ) .
Family Kingstoniidae Kingstonia seeiyi ( W a l c o t t ,
Family Olenidae
1912)
Olenids are k n o w n in the Ordovician of New York from
Cotypes U S N M 5 8 5 8 2 t o 5 8 5 8 4 Upper C a m b r i a n , Potsdam S a n d s t o n e . See Resser ( 1 9 4 2 ) .
at least three, possibly five, species of Triarthrus. T h e s e are small trilobites with a semicircular cephalon. T h e glabella is rectangular, curving gently in front. T h e SI and S2 glabellar furrows
Family Komaspididae
are distinct and curve toward the rear. S3 is usually faint. T h e
Komaspidids are small o p i s t h o p a r i a n trilobites with forward-
free cheeks are "yoked," m e a n i n g they are attached together
narrowing glabella. T h e eyes are characteristic as they are quite
anteriorly to the front center of the glabella and are lost as a
long, extending m o r e than h a l f the length of the glabella. T h e r e
single unit during the m o l t i n g process. T h e fixed cheeks flare
are genal spines. T h e pygidium is semicircular and roughly the
o u t w a r d f r o m the rear end of the palpebral lobes, crossing
same size as the c r a n i d i u m . T h e r e are only two or three axial rings
the genal angle. T h e r e is an occipital n o d e . T h e t h o r a x has 12 to
and pygidial pleurae.
15 s e g m e n t s . Triarthrus beckii and the early T. eatoni have axial
Interpleural furrows do not reach the
margin. T h e family is n o r m a l l y f o u n d from the Upper C a m b r i a n
nodes on all the t h o r a c i c segments.
to
question
( u p p e r ) W h e t s t o n e G u l f Shale does not have axial nodes on the
whether the b e l o w - m e n t i o n e d trilobite is in the correct family.
m o s t a n t e r i o r segments. T h e pygidium is very small and can be
"Carrickia is probably a p r o e t a c e a n ; it is definitely not a k o m a s -
distinguished f r o m the t h o r a x by the absence of intrapleural
p i d i d " (R. Ludvigsen 1997, private c o m m u n i c a t i o n ) .
furrows. See Ludvigsen and Tuffnell ( 1 9 8 3 , 1994) for a complete
the
Lower
Ordovician
(Treatise).
There
is
some
Triarthrus eatoni from the
review. "Carrickia" setoni
(Shaw,
1986) Triarthrus beckii (Green, 1832) Plate 170
Holotype N Y S M 12246 "Carrickia" setoni was described f r o m silicified material f r o m the Middle O r d o v i c i a n , lower M i d d l e Chazy. Additional material
Hypotype N Y S M 9892 Type
species.
Triarthrus
beckii
is
widely
distributed
in
was f o u n d in the upper lower C h a z y as well. M o s t of the m a t e -
Middle O r d o v i c i a n Trenton equivalent shales such as the Flat
rial is very small silicified s p e c i m e n s . T h e glabella tapers forward
Creek,
and from the dorsal view is parabolic to semicircular. T h e r e are
County. It has also been reported in s o m e lower Trenton L i m e -
no glabellar furrows. T h e eyes are set wide apart and e x t e n d f r o m
stones. Triarthrus beckii is primarily distinguished from T. eatoni
about o n e - t h i r d b a c k on the c r a n i d i u m to nearly the posterior
by the position of the palpebral lobe. On T. beckii the lobe is short
cephalic border. T h e t h o r a x is u n k n o w n . T h e pygidium is s e m i -
and the posterior e n d is opposite the S2 glabellar furrow. On T.
circular with a well-defined axis with two axial rings. T h e r e are
eatoni the palpebral lobe is significantly longer and extends to the
two pleurae. T h e pleural furrows do not quite reach the margin.
SI glabellar furrow. T h i s distinction is usually clear. In addition,
lower
Utica,
and
Dolgeville
Shales
in
Montgomery
This trilobite is the only representative of this n o r m a l l y upper
the glabella length and width are nearly equal with T. beckii, while
Middle C a m b r i a n
the glabella of T. eatoni is longer than wide. On s o m e specimens,
to Lower O r d o v i c i a n
family.
F o r location
however, such as those f r o m the Holland Patent site (see T. spin-
i n f o r m a t i o n , see Shaw ( 1 9 6 8 ) .
osus), b o t h characteristics of T. beckii and T. eatoni can be found. Ludvigsen and Tuffnell ( 1 9 9 4 ) indicated that the ranges of T.
Family Lonchocephalidae
beckii and T. eatoni significantly overlap. Plate 170 enables o n e to
Lonchocephalus ( B r a d l e y , 1 8 6 0 )
see the short palpebral length c o m p a r e d to T. eatoni (Plates 171
Plesiotypes U S N M 5 8 5 6 7 t o 5 8 5 7 0 Upper
Cambrian,
Potsdam
Sandstone,
Keesville,
Essex
County.
and 1 7 2 ) . Triarthrus eatoni (Hall, 1 8 3 8 ) Plates 171 and 172 Hypotypes N Y S M 9 8 9 3 , 9 8 9 4
Family Marjumiidae Modocia punctata
(Rasetti,
Triarthrus 1967)
Holotype U S N M 156687 M i d d l e C a m b r i a n , S t o c k p o r t Station, C o l u m b i a C o u n t y . See Bird and Rasetti ( 1 9 6 8 , p. 2 6 ) .
eatoni
is
a
common
trilobite
of
the
Upper
O r d o v i c i a n , upper Utica Shales and overlying Lorraine G r o u p shales. Many, if not m o s t , of the s p e c i m e n s labeled as T. eatoni f r o m the M i d d l e Ordovician shales are T. beckii. A complete meraspid growth series of this trilobite is k n o w n from collections
ORDER
167
PTYCHOPARIIDA
made by Walcott and Rust in the Utica Shale overlying the
Plethopeltis saratogensis
Steuben Limestone near Holland Patent, O n e i d a County. B e -
Holotype U S N M 58558
(Walcott,
1890)
Plate
175C
cause of its presence in Beecher's Trilobite Bed with superbly
Type species. T h i s species is f r o m the Upper C a m b r i a n , Hoyt
pyritized appendages, a great deal has been written c o n c e r n i n g
L i m e s t o n e , Lester State Park, Saratoga County. See Ludvigsen and
the structure of this trilobite (see W h i t t i n g t o n and A l m o n d
Westrop ( 1 9 8 3 ) .
( 1 9 8 7 ) and the references t h e r e i n ) . T h e protaspid of this trilobite reported from these beds, however, may be that of a proetid
Family Ptychopariidae
(G.
Ptychoparia
Edgecombe
1990,
private
communication).
Triarthrus
eatoni lived in deep, poorly oxygenated waters. Plate 172 shows a Beecher specimen with the pyritized appendages. T h e specimen in Plate 171 has all the characteristics of T. eatoni except
minuta
(Bradley,
1860)
S p e c i m e n M C Z 1045 Upper C a m b r i a n , P o t s d a m S a n d s t o n e , High Bridge, Keesville, Essex C o u n t y .
it lacks the axial nodes on the eight m o s t - a n t e r i o r t h o r a c i c segments.
Ptychoparia
matheri
(Walcott,
1912)
Types U S N M 5 8 5 8 5 t o 5 8 5 8 7 Triarthrus glaber
(Billings,
Upper C a m b r i a n , Potsdam S a n d s t o n e , W h i t e h a l l , Washington
1859)
County.
Syntypes G S C 1936e, h ; specimen U S N M T h e syntypes are from the Upper O r d o v i c i a n o f Q u e b e c . U n n u m b e r e d specimens in the U S N M from L o r r a i n e , Jefferson
Family Shumardiidae T h i s is a family of very small, blind trilobites without facial
County, bear this n a m e .
sutures and oval in o u t l i n e . T h e c e p h a l o n is semicircular with Triarthrus spinosus (Billings, 1 8 5 7 ) Plates 173 a n d 1 7 4
deep lateral glabellar furrows. T h e occipital ring is p r o m i n e n t .
Holotype U S N M 9 6 2 3 5 , hypotypes N Y S M 9 8 9 7 t o 9 9 0 0
T h e pygidial shape is variable, as are the n u m b e r of axial rings
R u e d e m a n n ( 1 9 2 6 ) found this n o r m a l l y Upper O r d o v i c i a n
( f o u r to seven). T h e i r family relationship is in d o u b t .
Canadian trilobite in collections m a d e by Walcott and Rust. It was found in the Utica Shales overlying the S t u e b e n L i m e s t o n e
Shumardia pusilla
near Holland Patent, O n e i d a County. T h i s olenid is distinguished
Hypotype N Y S M 9857
by having genal spines, an occipital spine, and t h o r a c i c spines
(Sars,
1835)
Lower O r d o v i c i a n Deepkill Shales.
from the eighth, ninth, and tenth t h o r a c i c segments. T h e r e are no axial nodes on the thoracic segments. T h e s p e c i m e n in plate 173
Family Solenopleuridae
is the holotype. Plate
Rimouskia
174 shows a s p e c i m e n f r o m O t t a w a ,
typica
(Resser,
1938)
Ontario.
Plesiotype U S N M 1 5 6 6 9 4
Family Plethopeltidae
Hill and Judson Point, C o l u m b i a County. See Bird and Rasetti
Type species. T h i s species is f r o m the Lower C a m b r i a n , Ashley Plethometopus
knopfi
(Lochman,
( 1 9 6 8 , p. 2 8 ) . Rasetti ( 1 9 6 7 ) classified Rimouskia as "family u n d e -
1946)
t e r m i n e d . " T h e Treatise placed it within this family.
Holotype Y P M 1 7 3 9 4 Upper C a m b r i a n , f r o m rocks in Dutchess C o u n t y referred to
Family Uncertain
as " H o y t D o l o s t o n e . "
Clelandia Plethopeltis granulosa
(Resser,
(Cleland,
1900)
F r o m the Lower O r d o v i c i a n Tribes Hill F o r m a t i o n . Westrop,
Holotype U S N M 5 8 5 6 1 Upper C a m b r i a n , Hoyt
parabola
H o l o t y p e PRI 5 0 7 0
1942) L i m e s t o n e , Saratoga County.
Ludvigsen and Westrop ( 1 9 8 3 ) .
See
K n o x , and Landing ( 1 9 9 3 ) reviewed the trilobite. T h e species is also f o u n d in Idaho and O k l a h o m a .
Appendix A Trilobites and Their Environments
Environment
Ordovician Chazy
Lagoonal
Ordovician Black River
Ordovician Trenton
Ordovician
Lowville Bathyurus Bumastoides
Reef/shoals
Reef limestone Thaleops Glaphurus Glaphurina Paraceraurus Niloides Uromystrum Plattillaenus Hyboaspis Isotelus Bumastus
Shoal margins
Calcarenite Plattillaenus Glaphurina Bumastoides Cybeloides Lonchodomas Calyptaulax
Watertown Raymondites Bathyurus Bumastoides lllaenus Isotelus Eoharpes
Steuben//C/'ngs Falls Calyptaulax Primaspis Hemiarges Flexicalymene
Sugar River/Den/ey Isotelus Primaspis Flexicalymene Ceraurus Cryplolithus
Napanee Isotelus Flexicalymene
Pulaski Flexicalymene Cryptolithus
Distal ramp
Canajoharie Gravicalymene Isotelus Triarthrus
Whetstone/ Frankfort Homotelus Triarthrus Cryptolithus
Upper slope
Dolgeville Triarthrus
Lower slope
Utica Triarthrus
Basin
Utica Triarthrus
Proximal ramp
Silty limestone Calyptaulax Cybeloides Lonchodomas Ceratocephala
Information on trilobites and their environment from the work of Carlton Brett, Gerald Kloc, and Thomas Whiteley. 168
Lorraine
TRILOBITES
Silurian
AND
THEIR
Silurian
Clinton
Lockport
Devonian
Helderberg
Devonian
Onondaga
Gasport Calymenids
U. Irondequoit Dalmanites Scutellum Spathocalymene
Lowest Rochester L. Irondequoit Deiphon Bumastus Dicranopeltis Trochurus Liocalymene Encrinurus Eophacops Shales
Upper Rochester Shales Willowvale Dalmanites Trimerus Liocalymene
Eramosa (basal) Encrinurus Dalmanites Calymenids
Devonian
Hamilton
Tully (lower) Scuttelum Pseudodechenella Harpidella
Chrysler/Thacrier Eurypterids
Neahga/Sodus Eophacops Calymenids
Lower Rochester Trimerus Calymene Dalmanites Radnoria Arctinurus Decoroproetus Bumastus
169
ENVIRONMENTS
Coeymans/Becrarr Odontochile Scutellum Proetus
Edgecliff (western) Maurotarion Mystrocephala 'Calymene" Synphoria Trypaulites Terataspis
Tichenor Otarion
Kalkberg/Becraft Paciphacops Coniproetus Scutellum Synphoroides
Moorehouse/ Clarence Harpidella Coronura Odontocephalus Viaphacops
Centerfield/Kashong Basidechenella Monodechenella Eldredgeops Harpidella Bellacartwrightia
New Scotland Paciphacops Kettneraspis Dicranurus Oinchoe Acanthopyge Neoprobilium Dalmanites Cordania
Seneca Viaphacops
Wanakah/ Windom Eldredgeops Pseudodechenella Bellacartwrightia Greenops Dipleura Monodechenella
Esopus
Nedrow Viaphacops Odontocephalus Kettneraspis
Ledyard Eldredgeops Greenops
Levanna Eldredgeops Greenops
Williamson Liocalymene
Marcellus Eldredgeops?
Appendix B The Photography
A l l of the p h o t o g r a p h s for this b o o k were taken with a fairly standard, single-lens reflex, 3 5 - m m c a m e r a e q u i p p e d with a m a c r o
the exposure system of the c a m e r a to give proper exposure regardless of the aperture.
focusing lens. W i t h few e x c e p t i o n s , the c a m e r a was placed on a
• Film. T h e preferred film was Kodak 25-speed color negative
copy stand, and electronic flash was always used for exposure. T h e
film because of its very high resolution. W h e n it b e c a m e no
specimens, preferably, were set on a " l a b - j a c k " s u p p o r t so they
longer available, Kodak Gold 100 was used, as it is the next
could be raised or lowered for focusing independent of the
sharpest available c o l o r negative film. C o l o r negative film was
camera o n c e the proper c o m p o s i t i o n was reached. T h e flash was
preferred over black and white film (which can be sharper) and
as close to o n - a x i s as the setup p e r m i t t e d . T h e e x p o s u r e was
slide film (which has p o o r exposure latitude and is not as
d e t e r m i n e d through the lens by the electronics of the c a m e r a .
s h a r p ) . T h e c o l o r negative films are fine enough in grain so
An aperture of fl 1 was used for very flat s p e c i m e n s and f 2 2 ,
graininess is not a p r o b l e m and the sharpness of the p h o t o -
for t h r e e - d i m e n s i o n a l s p e c i m e n s . T h e preferred films were c o l o r
graphic image is well above that of the image when digitized
negative films selected for the highest sharpness available. P r o -
(i.e., it is not a limiting factor in image quality). High-quality
cessing and printing were p e r f o r m e d by c o m m e r c i a l l y available
c o l o r negative processing is available anywhere in the c o u n t r y
sources.
(world?), and the c o l o r print is very useful for cataloging.
Dark
specimens
ammonium
usually
chloride.
This
benefited procedure
from was
whitening not
available
with for
specimens in m u s e u m s .
• E x p o s u r e . Electronic flash was preferred because (1) it stops all m o t i o n and ( 2 ) most c o l o r films are balanced for daylight e x p o sure. T h e r e is a m e a s u r a b l e , and theoretically known, falloff in
With a Nikon L S - 1 0 0 0 3 5 - m m film scanner, the resulting c o l o r
sharpness as a c a m e r a lens is stopped down beyond about f 11.
negatives were s c a n n e d directly into a c o m p u t e r r u n n i n g Adobe
Apertures between fl 1 and f22 were chosen to give the neces-
P h o t o s h o p software. All of the s c a n n i n g was at a resolution of
sary depth of field. Aperture 22 was only used when the speci-
2 7 0 0 pixels/inch
m e n had a lot of t h r e e - d i m e n s i o n a l character.
( 1 0 6 p i x e l s / m m ) . T h e s c a n n e d images were
adjusted with the autolevels c o m m a n d in P h o t o s h o p ; treated with
• S c a n n i n g . T h e p h o t o g r a p h i c images were scanned into the
unsharp masking. Scratches on the negative were r e t o u c h e d in
c o m p u t e r , as digital images are m u c h easier to manipulate
P h o t o s h o p ; this was the only r e t o u c h i n g d o n e to the image.
than are optical images in the traditional d a r k r o o m . O n c e o n e
( T h e r e were rare exceptions to this " n o r e t o u c h i n g " statement.
gets
W h e n glue bubbles in a repaired s p e c i m e n were t h o u g h t to be
t i m e difference between using the c o m p u t e r and the traditional
distracting, they were r e t o u c h e d away using the " c l o n e " t o o l — t h e
d a r k r o o m is orders of m a g n i t u d e . S c a n n i n g was d o n e at 2 7 0 0
same tool used to eliminate s c r a t c h e s ) . T h e digital images were
pixels/inch in order to have the m a x i m u m a m o u n t of infor-
then stored as T I F F files.
m a t i o n to work with in the c o m p u t e r . Images can always be
T h e images in the b o o k were adjusted for c o m p o s i t i o n in
through
the
learning
curve
with
digital
images, the
sized down with little loss in quality but sizing up always intro-
P h o t o s h o p and the final images were stored as T I F F files at a
duces potential p r o b l e m s . Occasionally the prints, if good
resolution o f 3 0 0 pixels/inch ( 1 1 . 8 p i x e l s / m m ) .
e n o u g h , were s c a n n e d into the c o m p u t e r with a flat bed scanner. O n e should use the m a x i m u m optical resolution of the
Some Specifics • C a m e r a s . T h e two cameras used exclusively were O l y m p u s O M - 2 N and O M - 4 T .
scanner. • Software. Adobe P h o t o s h o p is the m o s t - u s e d image-processing p r o g r a m available. A limited edition that is now on the market
• Lenses. T h e m a c r o lenses used were the O l y m p u s 5 0 - m m f3.5
for significantly less m o n e y has all the capability most needed
and the Vivitar 9 0 - m m f2.5. ( T h e Vivitar was preferred because
for this type of work. T h e levels c o m m a n d evaluates the image
the longer focal length allowed better c o m p o s i t i o n . )
and adjusts it to o c c u p y the gray-scale space that P h o t o s h o p
• Flash. T h e flash used was an O l y m p u s T - 3 2 , which couples with 170
can
handle.
This
is
important.
The
autolevels
function
THE
PHOTOGRAPHY
171
generally does an excellent j o b , but occasionally o n e will wish
further work is going to be d o n e on t h e m . Since a 3 5 - m m T I F F
to additionally adjust the image for lightness or darkness. To do
c o l o r image can be about 25 megabytes in size, o n e should con-
this, use the levels c o m m a n d and m o v e the center slider to get
sider storing images on a C D - R O M , as CD " b u r n e r s " are readily
the preferred image. U n s h a r p m a s k i n g e n h a n c e s edges and is
available and writable C D s are inexpensive.
also i m p o r t a n t . A n y t i m e an image goes through a lens, it loses
Printing. T h e ink-jet printers on the market can give near-
sharpness. T h i s happens both in the c a m e r a and in the scan-
photographic-quality
ners. Unsharp masking will regain the edge sharpness desired
white. Various c o n s u m e r groups and c o m p u t e r magazines rate
in the image.
the printers. T h e i r advice is usually s o u n d . T h e price range is
prints
in
either
color
or
black and
Stored images. Most publishers want images that have not been
large and is driven m o r e by p r i n t i n g speed than by final print
compressed. All compression algorithms throw s o m e i n f o r m a -
quality. In o t h e r words, within o n e manufacturer's printers,
tion away as redundant.
For a o n e t i m e c o m p r e s s i o n and
there will be little if any difference in print quality between
decompression and printing, it is unlikely that anyone will
those selling for $ 1 5 0 and those selling for $ 3 0 0 but the print-
that
ing speed may be significantly different. If you do not m i n d
previously have been compressed and then modified can result
waiting 5 to 10 m i n u t e s for an 8 x 10 c o l o r print, buy the less
in
is
expensive m o d e l . No specific r e c o m m e n d a t i o n s can be given
inescapable. By far the safest m o d e is to keep images in an
because the t e c h n o l o g y is m o v i n g t o o fast and any r e c o m m e n -
uncompressed m o d e ( T I F F ) and only c o m p r e s s t h e m when n o
dations will be o b s o l e t e within a year.
notice
changes
compression
in
the
artifacts
image. that
Compressing
reduce
image
images quality.
It
Glossary
F o r the geological t e r m s we were assisted by the use of Keary ( 1 9 9 6 ) and for the trilobite t e r m s , by W h i t t i n g t o n and Kelly (1997).
a u t o c h t h o n o u s . A term describing rock units in place where they were deposited (i.e., not t r a n s p o r t e d ) , axis. T h e longitudinal center line of an organism, ball-and-pillow-type structures.
a b a t h o c h r o a l . Having schizochroal eyes with less lenses and lacking stellar p r o j e c t i o n s ,
underlying m u d .
abaxial. Away or farther from the axial line, a c c r e t i o n a r y wedge. A
complex
basis (plural, b a s e s ) . T h e most proximal part of the trilobite,
of sediments
with
multiple
thrust faults resulting from the s c r a p e - o f f of s e d i m e n t , o n t o the
overridding
plate,
from
the
oceanside
plate
during
subduction. acritarchs.
R o u n d e d sandstone structures
resulting from the soft sediment settling of sandstone into
appendage structure. The basis attaches to the trilobite, and the o t h e r two parts of the appendage b r a n c h o f f from it. benthic (benthonic).
Living on the seafloor.
b e n t o n i t e s . Clay layers consisting of altered volcanic ash useful
A g r o u p of microfossils consisting of hollow, organic-
walled, unicellular vesicles, mostly 20 to
1 5 0 | i m in size.
in tracing stratigraphic h o r i z o n s , biofacies.
R o c k s with distinctive and characteristic fossils,
Known f r o m the P r e c a m b r i a n to the recent, they are used in
b i o h e r m s . An organic m o u n d or reef.
stratigraphic correlation.
b i o m e r e s . A t e r m used to describe periods of time in the C a m -
adaxial. Toward or closer to the axial line.
brian when there was an extinction event with nearshore trilo-
a e r o b i c . Able to live only where free oxygen is available.
bites and the area was repopulated from deeper-water species
a l l o c h t h o n o u s . A t e r m describing rock units that have been transported f r o m the site of their original deposition.
with differing functions.
a m a l g a m a t e d . Closely j o i n e d , inseparable rock units. a n a e r o b i c . Able to live or can o n l y live where free oxygen is absent.
b o r d e r . F o r the trilobite, a distinctive area around the margin of the cephalon or pygidium.
a n o x i c . A term describing an e n v i r o n m e n t where the c o n c e n t r a tion of oxygen is t o o low to support o x y g e n - b r e a t h i n g life. antennae
that evolved to o c c u p y the now-vacant ecological niches. b i r a m o u s . Having appendages that b r a n c h into two branches
(singular, a n t e n n a ) . Modified
jointed
and
extend
from
the
front,
appendages that are ventral
part
of the
cephalon.
b o u n d s t o n e s . Limestones
the
grains
were
bound
b r e c c i a s . R o c k units with included angular pieces, or clasts, of o t h e r b r o k e n - u p units. o t h e r units.
a n t e r i o r cephalic b o r d e r . T h e b o r d e r o n the forward part o f the cephalon generally b o u n d e d by the a n t e r i o r cephalic sutures. a p o d e m e s . Paired
projections
on
the
inner
surface
o f the
exoskeleton along the axial groove. T h e r e is o n e pair for each
cephalic b o r d e r . chamositic.
C o n t a i n i n g the iron mineral c h a m o s i t e .
c h e l i c e r a t e . A subphylum of a r t h r o p o d s without antennae and with
appendage. A p o d e m e s are the a t t a c h m e n t points
(pinchers).
for the
appendages to the exoskeleton.
chert.
a p o m o r p h y . A derived characteristic.
appendages.
animal
first
pair of appendages
modified as chelicerae
Microcrystalline quartz f o u n d within limestones, taxonomic
methodology
studying
relationships
using shared characteristics,
arenites. Sandstones with grain sizes f r o m 0.1 to 2 m m . a r t h r o p o d . An
the
cladistics. A
See apodeme.
T h e b o r d e r a r o u n d the margin o f the cephalon.
c e p h a l o n (plural, c e p h a l a ) . T h e head o f the trilobite.
t h o r a c i c segment and a pair for each cephalic and pygidial
172
which
b r e c c i a t e d . C o n t a i n i n g breccia or distinctive inclusions from
anterior. Toward the front or in front of.
appendifer.
in
together by o r g a n i s m s .
with
an
exoskeleton
and
class. In biology, a grouping just after the phylum of plants or jointed
animals having a similar basic structure. Trilobites are in the phylum A r t h r o p o d a and class Trilobita.
173
GLOSSARY clasts.
epifaunal. A t e r m describing o r g a n i s m s that live on the sea
Pieces of b r o k e n - u p rock units.
cleavage.
b o t t o m , either m o v i n g freely or attached,
Preferred direction of splitting of rocks.
epipelagic.
c o m m i n u t e d . Broken down into fine particles.
Living at or very close to the surface of the sea.
animal
etymology. T h e origin and d e v e l o p m e n t of a word or n a m e ,
with chordate characteristics; widely used in stratigraphic
exfoliated. Loss of the actual fossil, leaving an internal mold,
correlation.
exite. T h e outer or brachial b r a n c h of a trilobite's appendage,
c o n o d o n t s . Phosphatic
teeth
of
an
extinct
marine
conterminant. A condition where the h y p o s t o m e is under the anterior glabella and attached to the a n t e r i o r d o u b l u r e by a suture. tire fossil c o m m u n i t y . tal material.
T h e line for o p e n i n g or separation of the free cheek
families. G r o u p i n g of o r g a n i s m s with very similar characteristics. In t a x o n o m y , family is the g r o u p i n g after order and before
cotype. W h e n two or m o r e s p e c i m e n s are used to define a species
genus. firmgrounds. Sea b o t t o m s that have consolidated enough to
(term is no longer used), coxa. T h e part of an a r t h r o p o d appendage attached to the body, cranidium (plural, cranidia).
T h e central p o r t i o n o f the trilobite
cephalon, b o u n d e d by the facial sutures; basically the fixed
support s o m e f o r m s o f direct a t t a c h m e n t s , fixigenae (singular, f i x i g e n a ) . T h e f i x e d cheeks; p o r t i o n s o f the cheek area not lost by the o p e n i n g of the facial suture, flooding surfaces.
cheeks and the glabella, cross-stratification. Inclined bedding structure resulting f r o m
S e d i m e n t - s t a r v e d areas at the interface of two
very different rock units due to a rapid rise in sea level or a transgression event,
water- or wind-deposited grains. A trace fossil attributed to trilobite tracks or trails,
fluidize. To convert a particulate substrate with stable, semisolid characteristics into a fluid that can flow,
cuticle. T h e exoskeleton of the trilobite. degree. A term used to describe the n u m b e r of t h o r a c i c segments
flute. A groovelike physical m a r k i n g on the base of a rock unit resulting f r o m erosion in the underlying unit,
in trilobite meraspid. dendroid. A highly b r a n c h e d inclusion often seen on bedding planes.
foreland basin. A basin or deepening of a sea between a stable c r a t o n and m o u n t a i n building due to plate tectonics,
desiccation cracks. Cracks
in
fine-grained
sediments
result-
ing from aerial drying out; usually seen as p o l y g o n - s h a p e d structures. d i a c h r o n o u s . A stratigraphic term describing a unit that varies in age over its geographic range, diagenesis. Process by which physical, biological, and chemical changes alter a sediment or fossil from the t i m e of deposition to the present. Diplichnites.
A fossil trace believed to be tracks f r o m the a p -
pendages o f a r t h r o p o d s , distal. Away from a reference point. dorsal. Toward the upper surface of an animal while in its life position. doublure. A c o n t i n u a t i o n , by folding under, of the dorsal e x o skeleton on the ventral side. down warp. T h e side of a fault displaced downward. dysaerobic. Able to live in low-oxygen c o n d i t i o n s . dysoxic. A term used to describe a low-oxygen e n v i r o n m e n t that poorly supports oxygen-breathing o r g a n i s m s . ecdysis. T h e process of shedding the exoskeleton in order to grow larger. Consisting primarily o f c r i n o i d material.
endites. Inwardly directed projections on a s e g m e n t , p o d o m e r e , of a trilobite's walking leg. endopod.
facial suture.
from the c r a n i d i u m .
coquina. Limestones with a high density of a c c u m u l a t e d skele-
encrinal.
appendage. exoskeleton. T h e external support structure for arthropods.
coordinated stasis. L o n g - t e r m evolutionary stability for an e n -
Cruziana.
e x o p o d . T h e upper or brachial, breathing, b r a n c h of a trilobite's
The lower or walking b r a n c h of a trilobite's appendage.
genae (singular, g e n a ) . T h e cheeks of a trilobite; the areas lateral f r o m the central area of the glabella, genal angle. T h e angle f o r m e d where the anterior margin of the cephalon turns toward the axis, genal
spine. A
spine
directed
posteriorly
from
the
genal
angle. genus (plural, g e n e r a ) . T h e t a x o n o m i c grouping after family that denotes an increasingly similar evolutionary relationship. It is the g r o u p i n g just b e f o r e the actual species. glabella. T h e central, axial, part of a trilobite's c e p h a l o n . glabellar furrow. A furrow along the sides of the glabella paralleling the axis of the trilobite. gnathobases. T h e most proximal p r o j e c t i o n s o n the p o d o m e r e s of a trilobite's appendages. g o n a t o p a r i a n . T h e c o n d i t i o n where the posterior end o f the facial suture emerges on the genal angle. gradient
currents. Underwater
currents
flowing
downslope,
often carrying sediment into deeper water. grainstones. G r a n u l a r limestones with no included muds. graptolites.
Extinct a n i m a l s with a characteristic, often sawtooth,
shape, used in stratigraphic correlation. graywacke. A sandstone with greater than 1 5 % clay minerals. groove-casts. Grooves on an underlying layer caused by the m o v e m e n t of a stone along the b o t t o m . T h e s e grooves are expressed as casts on the underside of the overlying rock.
174
GLOSSARY
h e m i p e l a g i c . A term describing a deposit of fine-grained sedim e n t that has flowed d o w n s l o p e within a gradient current and c o m e to rest, settling out. no
L I , . . . Sequential
designation
for
the
lateral
glabellar
furrows, starting with the occipital furrow, LO. lowstand. T h e lowest sea level following a regression,
h o l a s p i d . T h e final growth phase of a trilobite; in most cases, signifies that
LO,
m o r e t h o r a c i c s e g m e n t s are added during
molting.
lutites. Very-fine-grained limestones. MaBP.
Million of years before present.
m a g m a s . M o l t e n rocks forced to the surface from underground
h o l o c h r o a l . Having c o m p o u n d eyes with a s m o o t h external surface.
chambers. m a r g i n a l lappets. Lappets radially projecting from the pygidial
h o l o t y p e . T h e single specimen used to define a species, hypersalinity. Salt c o n t e n t above what o n e measures in the ocean.
margin. m a r g i n a l spines. Spines radially projecting from the pygidial margin.
h y p o s t o m e (plural, h y p o s t o m a ) . A mineralized tergite on the ventral cephalon under the glabella.
meraspid. A cephalon
h y p o t y p e . A specimen described in the literature.
no
Iapetus. An ocean lying between p r o t o N o r t h A m e r i c a and the
molting.
growth and
further
the
phase
of
trilobites
protopygidium
thoracic
from
when
are separated
segments
are
the
to when
added
during
African c r a t o n . T h e closing of this o c e a n resulted in m a j o r
m e r a s p i s . An individual specimen in the meraspid phase,
m o u n t a i n building, the C a l a d o n i a n Orogeny.
m e t a m o r p h i c . A t e r m to describe rocks altered by heat and
impendent.
Having a c o n d i t i o n where the a n t e r i o r edge of the
h y p o s t o m e is posterior to the a n t e r i o r edge of the glabella. infaunal. A term describing o r g a n i s m s that live just under the surface of the sea b o t t o m . instar.
Recognizable phase d u r i n g the protaspid phase of trilo-
cally organic structure; used here to indicate the mineral structure of a trilobite's exoskeleton.
M a p s showing lines o f equal thickness o f rock
units.
m o r p h o l o g i c a l . Having
to
do
with
physical
shape
or
morphology.
isostatic. A term describing b u o y a n c y forces. karstic.
C o n t a i n i n g very-fine-grained limestones that form the
m a t r i x to fossil deposits; see also lutites. m i n e r a l i z e d . W h e n inorganic materials b e c o m e part of a basi-
bite growth. Isopach m a p s .
pressure. micritic.
m u d s t o n e s . R o c k s c o m p o s e d of consolidated muds with few
Having surface characteristics due to subsurface solution
of rocks. M a j o r c a v e - f o r m i n g areas often have karstic surfaces. K o n s e r v a t - L a g e r s t a t t e n . Fossil
deposits
with
very
unusually
good preservation o f the o r g a n i s m s , lag. Deposit in which the finer particles have been w i n n o w e d or washed away. lamella (pleural, l a m e l l a e ) . T h e horizontally separable part o f the c e p h a l o n , of trinucleids and harpids. A suture runs a r o u n d the outer edge of the c e p h a l o n , separating it into an upper and lower lamella. lappets. S h o r t , r o u n d e d p r o j e c t i o n s from the ends of the pleura. lateral glabellar f u r r o w s . S y m m e t r i c a l furrows in the glabella
larger particles. n a t e n t . A c o n d i t i o n where the h y p o s t o m e is below the anterior glabella but u n a t t a c h e d to the d o u b l u r e . n e o t y p e . T h e single specimen used to define a known species when the original type is lost or poorly defined. n o d e s . Small circular or oval raised areas on the exoskeleton. o b d u c t e d . A term used to describe rocks that have been forced over and above when two plates collide. occipital ring. Raised area at the posterior of the glabella running transverse across the axis and b o u n d e d by the glabellar furrows. ontogenetic.
Distintive phases of an animal's growth,
that are roughly perpendicular to the axis and end or start,
o n t o g e n y . T h e processes o f the growth o f a n organism,
from the glabellar furrow.
ooids.
lateral glabellar l o b e s . Bilateral lobes on the glabella separated by the lateral glabellar furrows. Laurentia. A continental land mass c o m p o s e d of the C a n a d i a n shield, G r e e n l a n d , parts o f western Europe, and o t h e r parts o f what b e c o m e s North A m e r i c a . l e c t o t y p e . T h e single s p e c i m e n selected to define the species
oolitic.
Small particles c o m p o s e d of concentric layers, C o n t a i n i n g oolites.
o p i s t h o p a r i a n . T h e condition where the posterior end o f the facial suture emerges on the posterior cephalic margin (i.e., toward the axis from the genal angle). order. T h e t a x o n o m i c grouping after class. orogenesis.
T h e building o f m o u n t a i n s .
when, in the original definition, a g r o u p of s p e c i m e n s , syn-
orogenic.
types or cotypes, were used.
ossicles. T h e n a m e given to individual e c h i n o d e r m plates.
librigenae (singular, l i b r i g e n a ) . Free cheeks. load casts. Depressions in an underlying s e d i m e n t f r o m overloading by the overlying layers; expressed as r o u n d e d p r o t r u sions on the base of the overlying layer.
Resulting from m o u n t a i n building.
packstones. Granular
limestones
with
mud
between
the
granules. palpebral area. Portion of the fixed cheek that is immediately adaxial to the eye.
175
GLOSSARY paralectotypes. W h e n
a
lectotype
is
chosen
from
a
type
group, syntypes or cotypes, the r e m a i n i n g s p e c i m e n s are paralectotypes. paratypes. S p e c i m e n s
radiolarian. M a r i n e , single-cell a n i m a l with an ornate silica shell.
from
the s a m e locations and h o r i z o n
as the holotype that have been used in the original species definition.
regression. T h e lowering of sea level. ridges. Elongated raised areas or s o m e t i m e s elongated, abrupt raised areas as in terrace ridges.
parsimonious. Used in cladistics to describe the closest relationship or fit in a grouping. phaselus. A m i n u t e oval structure believed to be a pre-protaspid phase in a trilobite's life cycle. animals; indicates a basic shared characteristic. planktic. Floating free in the surface of the sea. See planktic.
b o u n d e d by sutures; not present on all trilobites. Rusophycus.
A trace fossil attributed to trilobites; considered a
trilobite resting pit; often seen on the base of sandstones as a wedge-shaped raised area.
plastotype. A cast or m o l d of the original type s p e c i m e n . Having shared primitive characteristics, m e a n -
ing they are primitive to the group
d e n c e o f water rippling. Rodinia. A proposed P r e c a m b r i a n s u p e r c o n t i n e n t . rostral plate. A part of the ventral, a n t e r i o r b o r d e r of a trilobite
phylum (plural, phyla). T h e first t a x o n o m i c division of plants or
plesiomorphic.
rifting. T h e separation or pulling apart of continental plates. ripple m a r k s . M a r k s on a bedding plane due to preserved evi-
pelagic. Living in the o p e n ocean or deep sea.
planktonic.
pyritized. Replaced by pyrite in diagenesis.
(e.g., b i r a m o u s a p -
schizochroal. Having
eyes
sclerites.
ancestor to arthropods not exclusive to trilobites).
scoured. A sea b o t t o m
today).
the
lenses
are
distinctly
sclera. T h e area between the lenses of the schizochroal eye.
pendages are p l e s i o m o r p h i c as they represent a c o m m o n plesiotype. A specimen very similar to the type ( t e r m is not used
where
separate. Individual skeletal parts of c o m p l e x fossils. m a r k e d by c u r r e n t - m o v e d particles;
expressed as grooves or channels, setae (singular, s e t a ) . Small hairlike p r o j e c t i o n s f r o m various
pleura (plural, pleural). Lateral p o r t i o n of each t h o r a c i c segments, or the raised area separated by a groove on the pleural area of the pygidium. pleural spines. Spines projecting from the t h o r a c i c pleura. podomeres. T h e sections of the trilobite walking leg. posterior. Toward the rear or rearward. preglabellar field. An area immediately in front of the glabella separated from the cephalic margin by a groove, progradation. T h e buildup and extension o f deltaic sediments
parts of a trilobite. silicified. A term describing exoskeletal material or appendages that has been replaced with silica, soft sediment d e f o r m a t i o n .
Uneven, wavy surfaces at rock-layer
interfaces due to the settling of the upper layer into the still soft layer b e n e a t h it. SO, S I , . . .
Designations used t o identify the lateral grooves o r
sulcus in the trilobite glabella, speciation.
T h e process o f evolution o f o n e species into another,
within a basin as the result of sediment washed f r o m the land.
species. T h e smallest t a x o n o m i c division of life,
T h e weight of the sediments can cause the basin axis to m o v e
spines. Elongated, often p o i n t e d , exoskeletal p r o j e c t i o n s . Spines
away from the sediment source, proparian. T h e condition where the posterior end of the facial suture emerges in front of the genal angle, prosopon.
Exoskeletal o r n a m e n t a t i o n ,
protaspid. First unequivocal stage of a trilobite's life cycle, protaspis. An individual trilobite at the protaspid stage. Proterozoic. T h e late P r e c a m b r i a n . protocephalon. T h e anterior part of the meraspid that represents the future cephalon. Protopangea.
ject dorsally. s t o r m wave base.
M a x i m u m depth of the alteration of the sea
b o t t o m by s t o r m waves, stromatolites. M o u n d - s h a p e d ,
laminar
structures
formed
by
algae and c y a n o b a c t e r i a . stromatoporoids. Extinct
reef-forming
sponges
with
layered
calcite skeletons, subaerial. Exposed to the air.
Precambrian supercontinent ( R o d i n i a ) .
protopygidium. T h e p o s t e r i o r - m o s t part o f the trilobite during the meraspid stage,
subduction zone. T h e area d u r i n g plate collision where an o c e a n i c plate is forced under the continental plate. subsiding. T h e deepening of a basin b o t t o m due to tectonics or
proximal. Near, close to. punctuated equilibria.
can c o m e o f f radially to parts of the exoskeleton or may pro-
Periods of l o n g - t e r m evolutionary stabil-
ity followed by abrupt evolutionary changes. pustule. Small rounded, raised area on the exoskeleton. W h e n pustules are n u m e r o u s , the specimen is often referred to as pustulose. pygidium (plural, pygidia). T h e posterior or tail of a trilobite.
the weight of the overlying sediments. sulcus. A furrow or groove. supratidal. A t e r m describing an area at the water's edge that is above n o r m a l high tides but s u b m e r g e d during exceptional tides. suture. A line in the c e p h a l o n where the parts separate during the m o l t i n g process.
GLOSSARY
176 synapomorphies.
trace
Shared derived characteristics,
s y n j a c e n t . A t e r m used to describe overlying and underlying
s y s t e m a t i c s . T h e orderly classification o f organisms,
in
sedimentary
layers
tectophases. Phases during m o u n t a i n f o r m a t i o n and erosion
Treatise
on
Invertebrate
Paleontology:
or
walking
branch
of
a
trilobites
Part
O,
Anthro-
poda I (first edition) by M o o r e ( 1 9 5 9 ) . trough and h u m m o c k y cross-stratification.
from plate tectonics,
Cross-stratification
where the b o u n d i n g surfaces of the stratification are both s p o o n shaped (lower) and raised in the center ( u p p e r ) .
appendage. t e m p e s t i t e s . S e d i m e n t a r y f o r m a t i o n s resulting f r o m deposition
trough cross-bedding.
Cross-stratification where the lower sur-
face of the stratification is curved upward on the ends.
of sediments t r a n s p o r t e d as the result of storms. tergite. A part of the dorsal exoskeleton that separates along sutures or articulations.
t s u n a m i s . Tidal waves. t u b e r c l e s . Small p r o j e c t i o n s on the exoskeleton; often used to
t e r m i n a l axial s p i n e . A spine on the pygidium that projects posteriorly from the axial region.
imply a structure larger than a pustule yet not a spine, t u r b i d i t e s . S e d i m e n t layers from water-born sediments flowing
t e r r a c e lines. Elongated structures on the exoskeleton that are f o r m e d by m i c r o s t e p s .
d o w n s l o p e and c o m i n g to rest, turbidity currents.
t e r r a n e s . G e o g r a p h i c areas inserted within larger areas during
Turbulent currents o f sediment-laded water
flowing downslope. u n c o n f o r m i t y . A t i m e gap in the stratigraphic c o l u m n during
plate m o v e m e n t and c o n s o l i d a t i o n . C o n t a i n i n g sediments derived f r o m the erosion and
which no sediment was deposited or other rocks were eroded, ventral. T h e lower or under surface,
w a s h - o f f f r o m land. segments. The
meraspid phase. Treatise.
from its death to its discovery,
inner
transgressive lag. C o n c e n t r a t e d deposit formed during times of t r a n s i t o r y p y g i d i u m . T h e most posterior unit o f the trilobite
t a p h o n o m y . T h e study of processes involved with an o r g a n i s m
thoracic
structures
low sediment deposition and erosion during transgression.
t e r m , no longer applied),
terrigenous.
or
t r a n s g r e s s i o n . Sea level rising.
rock units. s y n t y p e s . O r g a n i s m s used to define the species (a t a x o n o m i c
telepodite. T h e
fossils. M a r k i n g s
believed to be due to the activity of living creatures,
articulated
parts
of
a
trilobite's
thorax. t h o r a c o p y g i d i u m . Trilobite fossil recovered w i t h o u t the c e p h alon, probably as a result of m o l t i n g . t h o r a x . T h e central b o d y o f the trilobite between the c e p h a l o n and the pygidium. t o p o t y p e . A s p e c i m e n f r o m the type l o c a t i o n .
vugs. Hollows within rocks. w i n n o w e d . A t e r m describing deposits of coarse particulate material f r o m which the fine sediments have been removed. w i n n o w i n g . T h e process o f currents removing f i n e particles f r o m a r o u n d coarser ones. X Y Z . A series of rocks exhibiting l o w - t o - h i g h - t o - l o w - e n e r g y deposition.
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1943b.
Black
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A m e r i c a n Journal o f Science 2 4 1 : 2 0 9 - 2 4 0 .
faunas, part
II.
Trilobite Index: Order-Family-Genus-Species T h e arrangement of the orders in this index reflects that in the trilobite Treatise (revised) (Kaesler 1 9 9 7 ) . Families, genera, and species are alphabetical.
ORPIR
FAMILY
GENUS
Agnostida
Diplagnostidae
Baltagnostus
angustilobus
118
Baltagnostus
stockportensis
56, 118
Peronopsis
evansi
56, 118
Peronopsis
primigenea
56, 118
Ptychagnostus
gibbus
56, 1 I 8
Ptychagnostus
punctuosus
56, 118
Peronopsidae Ptychagnostidae
Spinagnostidae
Calodiscidae
Eodiscidae
Hebediscidae Weymouthiidae
SPECIES
PAGE
Ptychagnostus
elegans
56, 118
Eoagnostus
acrorachis
56, 118
Eoagnostus
primigeneus
118
Hypagnostus
parvifrons
56, 1 18
Calodiscus
agnostoides
55, 119
Calodiscus
fissifrons
55, 119
Calodiscus
lobatus
55, 119
Calodiscus
meeki
55, 119
Calodiscus
occipitalis
55, 119
Calodiscus
reticulums
56,119
Calodiscus
schucherti
56, 119
Calodiscus
theokritoffi
56, 119
Calodiscus
walcotti
56, 119
Chelediscus
chathamsis
56, 119
Pagetia
bigranulosa
56, 119
Pagetia
connexa
56, 119
Pagetia
clytioides
56, 1 19
Pagetia
erratic
56, 1 19
Pagetia
laevis
119
Pagetides
amplifrons
56, 119 56, 119
Pagetides
elegans
Pagetides
leiopygus
56, 119
Pagetides
minutus
56, 119 56, 1 1 9
Pagetides
rupestris
Hebediscus
marginatus
119
Neopagetina
taconica
56, 119
PLATE
IE
Acidiscus
birdi
55, 119
Acidiscus
hexacauthus
55,119
1H
Acimetopus
bilobatus
55,119
1A
Analox
bipunctata
119
Analox
obtusa
119
Bathydiscus
dolichometopus
55, 119
Bolboparia
elongata
55,119
IF
191
192 ORDER
T R I L O B I T E
FAMILY
SPECIES
PAGE
V. ATI
Bolboparia
superba
55, 119
IE
Leptochilodiscus
punctulatus
56, 120
Litometopus
punctulatus
120
Mallagnostus
desideratus
120
Microdisctis
connexus
120
Oodiscus
binodosus
56, 120
GENUS
Oodhcus
longifrons
120
Oodiscus
subgranulatus
56, 120
Serrodiscus
griswoldi
56, 120
Serrodiscus
latus
120
Serrodiscus
speciosus
56, 120
Serrodiscus
spinulosus
56, 120
Serrodiscus
subclovatus
56, 120
Stigmadiscus
gibbosus
56, 120
Stigmadiscus
stenontetopus
56, 120
Weymoutliia
nobilis
56, 120 56, 118
Redlichiida
Holmiidae
Elliptocephala
asaphoides
Corynexochida
Dolichometopidae
Athabaskiella
proba
1 IS
Bathyuriscidella
socialis
118
Bathyuriscus
eboracensis
56, 118
Bathyuriscus
fibriatus
118
Corynexochidcs
expansus
56, 118
Fordaspis
nana
55, 56, 118
Kootenia
fordi
55, 56, 120
Olenoides
stissingcnsis
120
Olenoides
stockportensis
56
Bumastoides
aplatus
120
Bumastoides
bellevillensis
121
Bumastoides
billingsi
66, 121
Dorypygidae
Illaenidae
Styginidae
I N D E X
H,
I B , C, D, K
IK, 2
Bumastoides
comes
62
Bumastoides
gardenensis
62, 121
Bumastoides
globosus
62, 121
3
Bumastoides
holei
75, 121
4, 5
Bumastoides
milleri
66, 121
6
Bumastoides
porrectus
7 1 , 75, 121
7
Bumastoides
trentonensis
7 1 , 121
Illaenus
arcturus
121
IUaenus
consimilis
122
Illaenus
crassicauda
62
Illaenus
latidorsata
71
Nanillaenus
americanus
75, 122
Nanillaenus
conradi
7 1 , 122
Nanillaenus
latiaxiatus
66, 122
Nanillaenus
punctatus
62, 122
Nanillaenus
raymondi
62, 122
10A
Thaleops
longispina
62, 122
10B
Thaleops
ovata
62, 66, 122
Bumastus
ioxus
89, 123
11
Eobronteus
lunatus
78, 123
12
Eobronteus
62
S 9
TRILOBITE ORDER
Lichida
INDEX FAMILY
GENUS
SPECIES
PAGE
Failleana
indeterminata
66, 123
13
Illaenoides
cf.
trilohita
89, 123
14, 15
Platillaenus
erastusi
62, 123
Platillaenus
limbatus
123
Scutellum
barrandi
123
ScuteUum
niagarensis
85, 123
Scutellum
pompilius
98, 123
Scutellum
rochesterense
88, 89, 123
26B
Scutellum
senescens
116, 123
17
Scutellum
tullius
112,123
IS
Scutellum
wardi
93, 124
Zacanthoididae
Prozacanthoides
eatoni
56, 124
Lichidae
Acanthopyge
consanquinea
98, 124, 125
Acanthopyge
contusa
107, 124, 125
Amphilichas
conifrons
75, 124
Amphilichas
cornutus
75, 124
Amphilichas
minganensis
62, 124 7 1 , 124
Amphilichas
trentonensis
Arctinurus
boltoni
1, 18, 89, 126
Autoloxolichas
inconsuetus
7 1 , 126
Ceratolichas
dracon
107, 125, 126
Ceratolichas
PLATE
16
19
20, 21
107, 125, 126
Dicranopeltis
fragosa
126
Dicranopeltis
nereus
27, 89, 126
22, 23
Echinolichas
eriopsis
107, 126
24
Echinolichas
hispidus
105, 107, 125,
Hemiarges
paulianus
69, 7 1 , 126
25
lichid
sp.
126
26A
Oinochoe
bigsbyi
98, 125, 126
Oinochoe
pustulosis
98, 127
27
Richterarges
ptyonurus
127
28
Terataspis
grandis
17, 105, 107,
29
126
127
Odontopleuridae
Trochurus
bulbosa
127
Trochurus
halli
89, 127
Trochurus
phlyctainoides
127
Apianurus
narrawayi
62, 127
Ceratocara
shawi
127
Ceratocephala
triacantheis
62, 128
Diacanthaspis
parvula
75, 128
Dicranurus
elegantus
Dicranurus
hamatus
128
Kettneraspis
callicera
105, 107, 128
Kettneraspis
sp.
128
36
Kettneraspis
tuberculata
6, 98, 128
35 37, 38
30, 31
32 33
Meadowtownella
trentonensis
75, 128
Odontopleura
cerelepta
80, 128
Odontopleura
sp.
128
Primaspis?
crosota
128
34
39
194
TRILOBITE
ORDER
FAMILY
GENUS
Phacopida
Acastidae
asteropygin
SPECIES
PAGE
PLATE
129
40
112,129
41
Astropyginae aff. Greenops Bellacartwrightia
Calymenidae
Cheiruridae
INDEX
49 calderonae
Bellacartwrightia
calliteles
129
Bellacartwrightia
jennae
112, 129, 130
42, 43
Bellacartwrightia
phyllocaudata
112, 129, 130
44
Bellacartwrightia
pleione
107, 130, 131
Bellacartwrightia
whiteleyi
112,131
45
Bellacartwrightia
sp.
112,131
46, 47, 48
Greenops
barber i
112, 130, 131
50
Greenops
boothi
130, 131
51
Greenops
grabaui
11, 112, 131
52, 53,54
Greenops
sp.
11, 131
55, 56
Kennacryphaeus
harrisae
112, 131
Calymene
camerata
132
Calymene
conradi
80, 132
Calymene
niagarensis
9, 89, 132
58, 59
Calymene
platys
105, 107, 132
60
Calymene
singularis
93, 132
hi
calymenid
sp.
8, 27, 132
62, 63
Diacalymene
rostrata
85, 132
Diacalymene
sp.
132 132
57
64, 65
Diacalymene
vogdesi
Flexicalymene
granulosa
80, 133
Flexicalymene
meeki
25, 80, 133
Flexicalymene
senaria
14, 6 9 , 7 1 , 7 5 ,
67, 68, 69,
123
70
Gravicalymene
magnotuberculata
7 1 , 133
71,72
Liocalymene
clintoni
89, 133
73
Liocalymene
cresapensis
133
Acanthoparypha
sp.
62, 134
Acanthoparypha
trentonensis
134
Ceraurinella
latipyge
62, 134
86C
Ceraurinella
scofieldi
66, 134
74
Ceraurinus
marginatus
80, 134
75
Ceraurinus
sp.
134
Cerauropeltis
ruedemanni
62, 134
84C to E
Ceraurus
montyensis
134
Ceraurus
pleurexanthemus
9, 12, 19, 20,
Ceraurus
125
79, 80
Cheirurus
sp. sp.
135
81
Deiphon
pisum
89, 135
84B
Forteyops
approximus
135
Gabriceraurus
dentatus
7 1 , 75, 135
Gabriceraurus
hudsoni
62, 135
Heliomera
akocephala
62, 135
Kawina
chazyensis
62, 135
Kawina
vulcanus
62, 135
Nieszkowskia
satyrus
62, 135
Sphaerexochus
parvus
62, 135
Sphaerocoryphe
goodnovi
62, 135
76, 77, 78
2 2 , 7 1 , 134
82, 83
86B
TRILOBITE ORDER
195
INDEX FAMILY
GENUS
major
78, 135
robusta
75, 135
85
136
91B
Corycephalus
pygmaeus
107, 136
regalis
105, 137, 138
Dalmanites
aspinosus
137
Dalmanites
bisigmatus
101, 137
Dalmanites
limulurus limulurus
18, 27, 89, 137
Dalmanites
limulurus lunatus
137
pleuroptyx sp.
4(1
91A
russelli
137
nasutus
98, 137, 138
Neoprobilium
tridens
98, 137, 138 137
Odontochile
micrurus
98, 137
Odontochile
phacoptyx
101, 139
odontochilid Phalangocephalus
sp.
139
dentatus
88, 89
137
Forillonaria
litchfieldensis
87
98, 137
Neoprobilium Odontochile
92 43
138, 139
Cybeloides
ella
Cybeloides
prima
139
86B
Encrinurus
cf. raybesti
85, 93, 139
95
Encrinurus
139
139
96
Erratencrinurus
vigilans
69, 7 1 , 139
94
Physemataspis
insularis
139
86D
Brogniartella
trentonensis
139
sp.
Dipleura
dekayi
11, 140
Homalouotus
major
17, 101, 140
Trimerus Phacopidae
sp.
Corycephalus
Dalmanites
Homalonotidae
PLATI
Sphacrocoryphe
Dalmanites
Encrinuridae
PAGE
Sphaerocoryphe Staurocephalus Dalmanitidae
SPECIES
delphinocephalus
89, 93, 140
Trimerus
vanuxemi
101, 140
Burtonops
cristatus
102, 105, 140,
97, 98 99
141, 143 Eldredgeops Eldredgeops Eldredgeops
crassituberculatus rana rana norwoodensis
112, 141
100
2, 5 , 3 4 , 112,
101, 11
142
103, 11
112, 142
Eophacops
trisulcatus
85, 144
Paciphacops
hudsoniscus
141, 143, 144
Paciphacops
clarkci
101, 141, 143,
Paciphacops
logani
98, 107, 141,
Paciphacops
logani subsp. A
Phacopina
anceps
144
Phacops?
clarksoni
105, 141, 143,
Phacops?
iowensis
105, 11
144 143, 144
107
141, 144
144 112, 142, 144
108
Viaphacops
bombifrons
9, 107, 142,
109
Pliomerops
canadensis
62, 145
143, 145 Pliomeridae
112, 11 114
Pterygometopidae
Achatella
achates
23, 75, 78, 145
113
196 ORDER
TRILOBITE FAMILY
GENUS
SPECIES
PAGE
Calyptaulax
annulata
62, 145
Calyptaulax
callicephalus
9, 7 1 , 75, 78,
INDEX
PLATE
116,117
145
Synphoriidae
Calyptaulax
eboraceous
7 1 , 75, 78, 145
Calyptaulax
spbebryx
7 1 , 146
Chasmops? Eomonorachus
convexus
7 1 , 146
119
Anchiopella
anchiops
102, 105, 136,
120
Anchiopella
sobrinus
105, 146
Coronura
aspectans
107, 146
121, 122
Coronura
helena
107, 146
127B
Coronura
myrmecophorus
17, 107, 138,
Odontocephalus
aegeria
107, 147
123
Odontocephalus
bifidus
107, 147
124
Odontocephalus
coronatus
107, 147
Odontocephalus
humboltensis
107, 147
Odontocephalus
selenurus
107, 147
125
Odontocephalus
sp.
147
126
Schoharia
emarginata
105, 147
Schoharia
sp.
148
Synphoria
concinnus
105, 107, 148
Synphoria
sopita
Synphoria
stemmata
compacta
101, 148
Synphoria
stemmata
stemmata
101, 138, 148
Synphoroides
dolphi
148
Trypaulites
calypso
138, 148
Trypaulites
erinus
105, 107, 148
Trypaulites
macrops
107, 148
Cyphaspis
sp.
112, 149
Harpidella
craspedota
149
H a rpi delta
sp.
149
131
Harpidella
spinafrons
112, 149
129,130
7 1 , 146
118
146
147
Proetida
Aulacopleuridae
101, 148
Harpidella
stephanophora
107, 149
Maurotarion
minuscula
102, 105, 107,
Maurotarion
sp.
Otarion?
coelebs
149
Otarion?
diadema
107, 149
Otarion?
hudsonicum
80, 149
Otarion?
hybrida
107, 149
Otarion?
laevis
116, 149
Otarion?
matutinurn
78, 149
Otarion?
spinicaudatum
62, 149
Acidiphorus
whittingtoni
6 1 , 150
Bathyurellus
platypus
6 1 , 150
Bathyuropsis
schucherti
71
Bathyurus
cf. B. angelina
150
Bathyurus
extans
150
Bathyurus
johnsoni
66, 150
127A
128
149
Bathyuridae
132
133
TRILOBITE ORDER
197
INDEX FAMILY
Brachymetopidae
GENUS
SPECIES
PAGE 61
Bathyurus
perkinsi
Bathyurus
taurifrons
150
Benthamaspis
striata
6 1 , 150
Bolhocephalus
seelyi
Grinnellaspis
cf. G.
Raymondites
ingalli
7 1 , 150
Raymondites
longispinus
66, 150
PLATE
6 1 , 150 marginiata
6 1 , 150
Raymondites
spiniger
66, 150
Strigigenalis
cassinensis
6 1 , 151
Strigigenalis Uromystrum
caudatus brevispinum
6 1 , 151
Uromystrum
minor
62, 151
Australosutera
gemmaea
107, 112, 151
Cordania
becraftensis
101, 151
62, 151 134
Cordania
cyclurus
98, 151
Mystrocephala
arenicolus
105, 151
Mystrocephala
ornata
151
Mystrocephala
baccata
112,151
Mystrocephala
varicella
107, 151
Radnoria
sp.
151
Dimeropygidae
Dimeropyge
clintonensis
62, 151
Proetidae
Basidechenella
hesionea
105, 152, 153
Coniproetus
angustifrons
105, 152, 153
Coniproetus
conradi
105, 152, 153
Coniproetus
folliceps
107, 152, 154
Cornuproetus
beecheri
78, 80, 152,
Crassiproetus
brevispinus
107, 152, 154
Crassiproetus
crassimarginatus
107, 152, 154
Crassiproetus
neoturgitus
107, 154, 155
Crassiproetus
schohariensis
101, 153, 155
Crassiproetus
stummi
107, 153, 155
Cyphoproetus
wilsonae
7 1 , 155
Dechenella
haldemani
112, 154, 155
138
Decoroproetus
corycoeus
89, 155
139, 140
135
136
153
Gerastos
protuberans
153, 155
Hedstroemia
pachydermata
153, 155
Mannopyge
halli
107, 154, 155
Monodechenella
macrocephala
9, 112, 154, 155
Proetus
artiaxis
93, 153, 156
Proetus
clelandi
62, 153, 156
Proetus
hesione
153
Proetus
jejunus
112, 154, 156
Proetus
marginalis
154,156
Proetus
microgemma
154, 156
Proetus
parviusculus
153, 156
Proetus
spurlocki
80, 153, 156
Proetus
tenuisulcatus
93, 153, 156
Proetus
undulostriatulus
153, 156
proetid
sp.
156
Pseudodechenella
arkonensis
112, 154, 156
Pseudodechenella
canaliculata
107, 153, 157
137
141
142
TRILOBITE
198 ORDER
FAMILY
INDEX
GENUS
SPECIES
PAGE
PLATE
Pseudodechenella
clara
107, 154, 157
143
Pseudodechenella
rowi
112, 154, 157
144, 145 146, 147
Asaphida
Asaphidae
Basilicus
romingeri
157
Basilicas
ulrichi
66, 157 66, 157
Basilicus
vetustus
Basilicus
whittingtoni
17, 62, 158
Basiliella
barrandi
66, 158
Belle font ia
gyracanthus
6 1 , 158
Ectenaspis?
homalonotoides
66, 158
Homotelus
stegops
80, 158
Hyboaspis
depressa
62, 158
Isoteloidcs
angusticaudus
62, 158
Isoteloides
canalis
6 1 , 6 2 , 158
Isoteloides
peri
6 1 , 158
Isoteloides
whitfieldi
61
lsotelus
annectans
159
Isotelus
beta
62
lsotelus
giganteus
17, 62, 159
Isotelus
g'gas
148
149
1, 12, 14, 17,
150, 151,
2 3 , 7 1 , 7 5 , 159
152, 153
Isotelus
harrisi
62, 159
Isotelus
jacobus
7 1 , 159
Isotelus
latus
7 1 , 159
Isotelus
maximus
9, 17, 78, 159
Isotelus
platycephalus
1, 159
154, 155, 156, 157
Isotelus
pulaskiensis
80, 160
Isotelus
simplex
66, 160
Isotelus
walcotti
3, 75, 160
Niloides
perkinsi
62, 160
Pseudogygites
latimarginatus
80, 160
Vogdesia
bear si
62, 160
Vogdesia
obtusus
62, 160
Idahoiidae
Saratogia
calcifera
5 1 , 160
Pterocephaliidae
Cameraspis
convexa
5 1 , 160
Cameraspis
sp.
160
Conaspis
whitehallensis
160
Idiomesus Kiethiella
spdepressa
5 1 , 161
Lonchodoinas
chaziensis
62, 161
Lonchodonias
halli
62, 161
Lonchodoinas
hastatus
78, 161
Apatokephaloides
sp.
161
Hypodicranotus
striatulus
23, 75, 161
Remopleurides
canadensis
62, 161
Reniopleuridcs
linguatus
78, 161
Remopleurides
tumidus
78, 161
Richardsonella
sp.
101
Roberviella
brevilingua
6 1 , 161
Ptychaspididac
Raphiophoridae
Remopleurididae
158 159
175B
161
160, 161, 162
TRILOBITE ORDER
199
INDEX FAMILY Saukiidae
Symphysurinidae Trinucleidae
GENUS
SPECIES
PAGE 5 1 , 162
Hoytaspis
speciosa
Prosaukia
briarcliffensis
162
Prosaukia
hartti
5 1 , 162
Prosaukia
tribulis
5 1 , 162
Symphysurina
convexa
6 1 , 162
Symphysurina
woosteri
6 1 , 162
Cryptolithus
bchulus
20, 23, 28,
PLATE
175A
163
78, 80, 162 Cryptolithus
loretlensis
11,28, 6 9 , 7 1 ,
164, 165
162
Ptychopariida
Conocoryphidae Dokimocephalidae l-.lviniidae
Glaphuridae Harpidae
Cryptolithus
tcsseUatus
28, 69, 7 1 , 163
Trctaspis
diademata
78, 163
Tretaspis
reticulata
78, 163
Atops
trilineatus
55, 163
Conocoryphe
verrucosa
163
Sulcocephalus
saratogensis
163
166, 167
Calocephalites
minimus
5 1 , 163
Dellea
landingi
5 1 , 163
Ih-llca
saratogensis
5 1 , 164
1 )rabia
curtoccipita
5 1 , 164
Drabia
menusa
5 1 , 164
Elvinia
granulata
5 1 , 164
Glaphurina
lamottensis
62, 165
168B
Glaphurus
pustulosus
62, 165
168 A
Dolichoharpes
sp.
62, 165
Eoharpes
pustulosus
66, 165
Hibbertia
ottawaensis
165
Hibbcrtia
sp.
62, 165
167C
Hibbertia
valcourensis
62, 165
169A, B
Scotoharpes
cassiuensis
6 1 , 165
169D
Hystricurus
conicus
6 1 , 165
Hystricurus
crotalifrons
6 1 , 165
Hystricurus
ellipticus
6 1 , 165
Hystricurus
oculilunatus
6 1 , 166
Kingstoniidae
Kingstonia
seelyi
166
Komaspididae
Carrickia
setoni
62, 166
Lonchocephalidae
Lonchocephalus
sp.
166
Marjumiidae
Modocia
punctata
166
Menomoniidae
Bolaspidclla
fisheri
56, 166
Olenidae
Triarthrus
beckii
7 1 , 76, 166
170
Triarthrus
eatoni
14, 19, 20, 22,
171, 172
Hystricuridae
23, 78, 80, 166
Plethopeltidae
Ptychopariidae
Uncertain
Triarthrus
ghiber
80, 167
Triarthrus
spinosus
80, 167
Plethoinetopus
knopfi
167
Plethopeltis
granulosa
5 1 , 167
Plethopeltis
saratogensis
5 1 , 167
Ptychoparia
minuta
167
Ptychoparia
matheri
167
Shumardiidae
Shumardia
pusilla
6 1 , 167
Solenopleuridae
Rimouskia
typica
56, 167
Uncertain
Clelandia
parabola
167
173, 174
175C
Index
Abrasion, corrosion, and encrustation, 37
Cabot Head Shales, 83
Daedalus,
Caladonian Orogeny, 83, 100
Dawes Sandstone, 86
85
Cambrian allochthon, 51-56
Day Point F o r m a t i o n , 62
Cambrian autochthon, 4 9 - 5 1
death, 32
Agnostida, 117
Cambrian Period, 46-56
Death, decay and disarticulation, 32, 35
Agnostina, 117
C a m b r i a n stratigraphic charts, 52,
Acadian Orogeny, 49, 97, 99, 100, 105, 107, 110, 112, 115, 116
Alden pyrite beds, 111
55
1 )e( lew Formation, 90 Decker F o r m a t i o n , 95
Algonquin A r c h , 85, 86
Camillus F o r m a t i o n , 109
Alsen Formation, 99, 100, 101
Canajoharie A r c h , 69
Deep Run Member, 111
Ammonoosuc island arc, 6 1 , 62
Canajoharie Shale, 76
Deer River Shale, 76, 78
Amsterdam Formation, 68, 70
Cardiff F o r m a t i o n , 109
D e l p h i Station Member, 110
apodemes, 12
Carlisle Center Sandstone, 102
Denley F o r m a t i o n , 70, 7 1 , 72, 73, 74
appendages, 17, 19, 20
Catskill facies, 115
D e n m a r k F o r m a t i o n , 71
Arthrophycus,
Cedar Valley Limestone, 112
Devonian Period, 95-116
articulated remains, 33-35
cephalic border, 8
Devonian stratigraphic charts, 96, 97, 103,
Asaphida, 157
cephalic spine, 6
Ashokan Formation, 110
cephalic sutures, 9
Austin Glen Formation, 55, 64, 66, 81
cephalon, 5, 8
Dolgeville F o r m a t i o n , 76, 77, 78
Avalonia, 49, 100, 116
Centerfield Member, 110
doublure, 12
axial lobe, 5
Chazy G r o u p , 59, 62, 63
85
Chazy stratigraphic chart, 63
Deep K i l l F o r m a t i o n , 55, 61
108, 115 disarticulation, 34
Early Devonian, 96
Bald H i l l bentonite, 100
C h e m u n g facies, 115
Early Silurian, 83-85
Baltica, 49, 83
Chenango Member, 110
Eastern Trenton equivalents and Utica
basis, 19, 20
Cherokee U n c o n f o r m i t y , 80, 8 1 , 83,
Beaver Dam Shale, 102
84
Shale, 76-78 Edgecliff Member, 105
Becraft Limestone, 99, 100, 101
Cherry Valley Limestone, 109
eggs, 13
Beecher's Trilobite Bed, 17, 28, 40, 78
Chestnut Street bed, 107
endites, 19, 21
Beekmantown G r o u p , 57, 61
Chittenango Shale Member, 60
Eodiscina, 118
Bertie G r o u p , 83, 95
City Brook bed, 71
Eramosa F o r m a t i o n , 93
b i o h e r m , 62, 88, 90, 9 1 , 92, 105
cladistics, 30-31
l.sopus Formation, 101, 102
biostratinomy, 32
C l i n t o n G r o u p , 83, 84, 85
e v o l u t i o n , 30
Black River G r o u p , 59, 64, 67
C l i n t o n i r o n ores, 85
exites, 19
Bloomsburg Formation, 94
Cobleskill Limestone, 95
exoskeleton, 4 - 6
Bois Blanc Formation, 102
Coeymans Member, 96, 98, 101
exoskeletons w i t h attached fauna, 18
brachial appendage, 19, 20
Cole H i l l tongue, 110
eyes, 7
Bridgewater Member, 109
C o l u m b u s Limestone, 105
Bridport Member, 61
Corynexochida, 118
Findley A r c h , 85
Brown's Creek bed, 4 1 , 111
cranidium, 7
fixed cheek, 8
Browns Pond f o r m a t i o n , 53, 55
Creek phase (Tippecanoe Supersequence),
Flat Creek F o r m a t i o n , 76
Burgess Shale, 17
62, 64, 68
Fonda Member, 60
Burleigh H i l l Member, 89
C r o w n Point F o r m a t i o n , 62
Fort Cassin F o r m a t i o n , 60, 61
Butternut Member, 110
Cruziana,
fossil diagenesis, 32, 37-40
102
201
202 Fragmentation, and biased preservation, 36-37
INDEX Irondequoit Limestone, 87, 88, 91
m o l t i n g , 14, 15
Ivy Point Member, 111
Moorehouse Member, 105
Frankfort F o r m a t i o n , 78, 80, 81
Moscow F o r m a t i o n , 111
free cheek, 8
Jamesville Member, 98
M o t t v i l l e Member, 110
Frontenac A r c h , 57
Jaycox Member, 111
M o u n t M a r i o n Formation, 106, 109
Galway Formation, 51
Jeffersonville Limestone, 105
M o u n t M e r i n o Formation, 55, 63
Joshua Coral bed, 111
Moyer Creek Member, 78 M u r d e r Creek Beds, 42
Gasport F o r m a t i o n , 90, 92
muscles, 22
genal angle, 10
Kalkberg F o r m a t i o n , 96, 98, 101
genal spine, 6
Kashong Member, 111
Genesee Formation, 115
Kaskaskia Supersequence, 100
Napanee F o r m a t i o n , 67, 68, 70
Geneseo Shale, 112, 114, 115
Keefer F o r m a t i o n , 89
Nassau F o r m a t i o n , 53
glabella, 7
Keyser F o r m a t i o n , 95
Neahga Shale, 85
glabellar furrows, 8
Kings Falls Limestone, 69, 70
Nedrow Member, 104, 105
glabellar lobes, 8
K i r k l a n d F o r m a t i o n , 89
neotype, 3
Glens Falls Limestone, 69
Knox U n c o n f o r m i t y , 57, 60, 6 1 , 62, 63, 64
New Scotland Limestone, 98, 101
Glenerie Limestone, 101
Kodak Sandstone, 84, 85
Niagara Gorge, 88
gnathobases, 19
Lagerstatten, 17, 4 0 - 4 2
N o r m a n s k i l l G r o u p , 63
Glenmark Shale, 90
nodes, 6
Goat Island F o r m a t i o n , 90
lappets, 10
gonatoparion cephalic suture, 9
Late Devonian strata, 115-116
Oak Orchard Member, 93
Gondwana, 96, 100
Late Early Devonian, 96-100
Oatka Creek Shale, 109
Granville Shale, 53
Late O r d o v i c i a n , 78-81
o b r u t i o n , 34
"Grabau Trilobite Beds", 111
Late Silurian, 93-95
Ogdensburg Formation, 60
Grenville Orogeny, 43
Laurentia, 45, 49, 56, 6 1 , 100, 116
Olney Member, 98
Grenville rocks, 45, 46, 47, 48
Ledyard Member, 110, 111
Onondaga G r o u p , 102, 103, 105, 106
Grimsby F o r m a t i o n , 83
Leicester Pyrite, 112
Onondaga Indian Nations Ash, 105
Gull River F o r m a t i o n , 64
LeRoy bed, 109
Ontogeny, 13-17
gut, 22
Levanna Shale, 110
opisthoparion cephalic suture, 19
Lewiston Member, 89
Ordovician allochthonous rocks, 61
Halihan H i l l beds, 109
Lichida, 124
Ordovician Period, 56-81
H a m i l t o n G r o u p , 107, 108
life-mode, 21-30
Ordovician stratigraphic chart, 57
Hannacroix Member, 98
Little Falls F o r m a t i o n , 50, 51
Oriskany Sandstone, 101
Hasenclever Member, 78
Lockport G r o u p , 83, 90-93
Oswego F o r m a t i o n , 78, 79, 80
Hatch H i l l F o r m a t i o n , 55, 56, 61
Lorraine G r o u p , 78
Otisco Shale, 111
heart, 22
Lowville F o r m a t i o n , 64, 65
Otsquago F o r m a t i o n , 86
Helderberg G r o u p , 96
Ludlowville F o r m a t i o n , 108, 110, 113
hepatopancreatic organ, 22
Palatine Bridge Member, 60
Herkimer F o r m a t i o n , 87, 89
Mackenzie F o r m a t i o n , 93
H i g h Falls Ash, 73, 74
M a n i t o u l i n Dolostone, 83
Paleozoic stratigraphic charts, 44, 45
Hillier Limestone, 75, 79
Manlius F o r m a t i o n , 96, 101
palpebral lobe, 5, 7
holaspid, 13, 14
M a n o r k i l l F o r m a t i o n , 110
Pamelia F o r m a t i o n , 64
holochroal eye, 7, 9
M a p l e w o o d Shale, 84, 85
paratype, 3
holotype, 3
Marcellus F o r m a t i o n , 105, 109
Pecksport Shale, 109
House Creek F o r m a t i o n , 64
Medina G r o u p (Sandstone), 82, 83, 84, 85
Penfield Formation, 90
Hoyt Formation, 5 1 , 54
Menteth Limestone, 111, 113
Penn Dixie Quarry, 42
hypostome, 12
meraspid, 13, 14
perforations, 11
hypotype, 3
M i d d l e and Upper Trenton G r o u p , 71-76
Phacopida, 128
M i d d l e Granville Shale, 55
phaselus, 13
Iapetus Ocean (Protoatlantic), 46, 49, 61
M i d d l e Devonian, 105-114
Phytopsis, 64, 65, 69
I l i o n F o r m a t i o n , 90, 93
M i d d l e O r d o v i c i a n , 62-78
pits, 11
Indian Castle F o r m a t i o n , 76, 77
M i d d l e Ordovician allochthonous rocks,
plastotype, 3
Indian River F o r m a t i o n , 55, 6 1 , 63, 78 internal anatomy, 2 1 , 22
62-64 M i d d l e Silurian, 85-93
Paleozoic geology, 43-116
Plattekill F o r m a t i o n , 110 pleural lobes, 5
INDEX
203
podomeres, 19, 21
schizochroal eye, 7, 9
Tribes H i l l F o r m a t i o n , 57, 60
Poland Member, 7 1 , 72, 73
Schodack Limestone, 55
trilobite injury, 18, 26, 27
Pompey Member, 110
Schoharie F o r m a t i o n , 102
trilobite Lagerstatten in New York, 17,
Pools Brook Member, 98
Schoharie G r i t , 102
Port Ewen Formation, 99, 100, 101
Selinsgrove F o r m a t i o n , 107
Trilobite M o u n t a i n , 100
Port Jervis Formation, 100
setae, 19
trilobite names, 2
Portage facies, 115
Shadow Lake F o r m a t i o n , 64
trilobite preservation, 34
Potsdam Sandstone, 50, 51,53
Shawangunk, 85
trilobite shape, 23
40
Poulteney Formation, 61
Silurian Period, 81-95
trilobite size, 17
Power Glen Shale, 83, 84
Silurian stratigraphic chart, 82
Tristates G r o u p , 96, 101-106
Prasopora, 7 1 , 76
S k u n n e m u n k Outlier, 100, 101
Trocholites,
preglabellar field, 10
Sloss Supersequences, 62
Truthville Shale, 53, 55
71
Prelude to the Paleozoic, 43-46
Smoke Creek beds, 42
Tully Limestone, 112, 114
Proetida, 148
Snake H i l l F o r m a t i o n , 70, 76
Tuscarora F o r m a t i o n , 80, 83, 85
proparion cephalic suture, 9
Sodus Shale F o r m a t i o n , 85
Tutelo Phase (Tippecanoe Supersequence),
protaspid, 13, 14
soft body parts, 17
Ptychopariida, 163
soft tissue decay, 33
83, 96
Pulaski Member, 76, 79, 80
Solsville Sandstone, 109
pustules, 6
Sonyea G r o u p , 116
U n i o n Springs F o r m a t i o n , 106, 107, 109 Upper C l i n t o n G r o u p , 86-90
pygidial spine, 6
Stafford Member, 110
Upper O r d o v i c i a n Oswego and Queenston
p y g i d i u m , 5, 7, 10
Staghorn Point, 111
pyritization, 9, 2 1 , 37, 38, 39
Steuben F o r m a t i o n , 75, 78
Queenston Formation, 78, 80, 84
stomach, 22
Valcour F o r m a t i o n , 62
Stony H o l l o w Member, 109
Valley Brook Shale, 76
stromatolites, 5 1 , 54, 94, 112
ventral anatomy, 12, 28
Rathbun Member, 69, 71
Sugar River F o r m a t i o n , 69
Vernon F o r m a t i o n , 94
Ravenna Member, 98
syntype, 3
volcanic island arc, 56
Redlichiida, 118
Syracuse F o r m a t i o n , 95
formations, 80 Utica Shale G r o u p , 76, 78
Stockbridge Member, 60
Rafinesquina,
75
Walcott-Rust Q u a r r y beds, 17, 4 1 , 74,
Retsof beds, 111 Richmond Group, 80
Taconic allocthon, 6 1 , 62, 68
Rickard H i l l Member, 102
Taconic Orogeny, 53, 56, 6 1 , 76, 82
Wallbridge U n c o n f o r m i t y , 101, 102, 104
75
Rochdale Formation, 61
taphofacies, 40
Wanakah Member, 111
Rochester Shale, 4 1 , 87, 88, 89, 91
terminal spine, 10
Ward Siltstone Member, 61
Rockway Formation, 86, 91
Tetradium, 64, 69
Watertown F o r m a t i o n , 64, 66, 67, 68
Rodinia, 43, 48
Thatcher Member, 96
West Falls G r o u p , 115
Rondout Group, 8 1 , 8 3 , 9 5
Theresa Dolostone, 5 1 , 60
Westmoreland, 86
Rose H i l l Shale, 86
thoracic segments, 10
Whetstone G u l f Member, 78
Rusophycus, 83, 85, 89
thoracic spines, 6
W h i r l p o o l Sandstone, 83, 84
Russia Member, 7 1 , 72, 74
thorax, 5
Whitehall F o r m a t i o n , 54, 60
Rust Formation, 72, 73, 74, 78
T h o r o l d Sandstone, 85
W i l l i a m s o n F o r m a t i o n , 90
Rysedorph H i l l conglomerate, 76
Tichenor Member, 111, 113
W i l l i a m s o n - W i l l o w v a l e shales, 86
Tioga bentonite, 105
W i n d o m Member, 112, 113, 114
Tippecanoe Supersequence, 62, 64, 68, 83,
W i n c h e l l Creek Member, 60
Salina Group, 83, 93, 94 Salinic Orogeny, 83, 94
96
Wintergreen Flat beds, 76
Sauk Supersequence, 49, 60, 62
Tonoloway F o r m a t i o n , 95
Wolcott F o r m a t i o n , 86
Sauk Unconformity, 61
trace fossils, 24, 25
W o l f H o l l o w Member, 60
Sauquoit Shale, 8 1 , 86
Transport and reorientation, 35-36
Schenectady Formation, 78, 79, 80
Trenton G r o u p , 68, 70
Zoophycos,
102
Plates T h e specimens on the following pages were p h o t o g r a p h e d and reproduced with the permission of their owners. T h e scale bars are 1 cm except where n o t e d .
ORDER A G N O S T I D A
Suborder Eodiscina
PLATE 1. Eodiscid trilobites from the Early Cambrian allochthonous rocks of New York. A. Acimetopus bilobatus cephalon from Columbia County. NYSM 17020. B. Serrodiscus speciosus from Columbia County. USNM 156592. Articulated specimens are rare in these rocks. C. Serrodiscus speciosus cephalon from Rensselaer County. NYSM 17018. D. Serrodiscus speciosus pygidium from Rensselaer County. NYSM 17019. E. Bolboparia superba cephalon from Columbia County. USNM 145998 (holotype). F. Bolboparia elongata pygidium from Columbia County. USNM 146002b (paratype). G. Calodiscus reticulatus cephalon from Columbia County. USNM 146006 (holotype). H. Acidiscus hexacanthus cephalon from Columbia County. USNM 145989 (holotype). I. Acidiscus hexacanthus pygidium from Columbia County. USNM 156574. J. Litometopus longispinus cephalon from Columbia County. USNM 146012. K. Cephala of Serrodiscus speciosus and Elliptocephala asaphoides from Rensselaer County. NYSM 17021.
ORDER R E D L I C H I I D A
Family Holmiidae
PLATE 2. Elliptocephala asaphoides from the Lower Cambrian Schodack Formation in Washington County. The cephalon is 100mm wide. Articulated specimens of this trilobite are very rare. USNM 18350.
ORDER C O R Y N E X O C H I D A
Family lllaenidae
PLATE 3. Bumastoides globosus from the Middle Ordovician Chazy Group, Valcour Formation, Valcour Island, Clinton County. The trilobite is 21 mm long. NYSM 12481.
PLATE 4. Bumastoides holei from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. The trilobite is 26 mm long. MCZ 3756.
PLATE 5. Bumastoides holei from the Middle Ordovician Rust Formation, Trenton Group Walcott-Rust Quarry, Herkimer County. The trilobite is 37mm long. MCZ 115909.
PLATE 6. Bumastoides milleri from the Middle Ordovician Trenton Group in Watertown, Jefferson County. The specimen is 25mm long. PRI 49621.
PLATE 7. Bumastoides porrectus from the Middle Ordovician Rust Formation of the Trenton Group, WalcottRust Quarry, Herkimer County. The trilobite is 23mm long. MCZ 101147.
PLATE 8. Nanillaenus americanus from the Middle Ordovician Rust Formation of the Trenton Group at the Walcott-Rust Quarry, Herkimer County. The trilobite is 20mm long. MCZ 707.
PLATE 9. Nanillaenus latiaxiatus from the Middle Ordovician in the Bowmanville Quarry, Ontario. This trilobite is reported in New York. The trilobite is 36mm long. In the collection of William Pinch.
PLATE 10. Illaenids from the Middle Ordovician Chazy Group. A. Nanillaenus ? raymondifrom the Day Point Formation, Valcour, Clinton County. NYSM 12491 (holotype). B. Thaleops longispina from the Crown Point Formation, Essex County. NYSM 12922 (holotype).
ORDER C O R Y N E X O C H I D A
Family Styginidae
PLATE 11. Bumastus ioxus from the Lower Silurian Rochester Shale in a commercial quarry near Middleport, Orleans County. The trilobite is 91 mm long. In the collection of Kent Smith.
PLATE 12. Eobronteus lunatus from the Middle Ordovician Snake Hill Shale, Snake Hill, Saratoga, Saratoga County. The trilobite is 45 mm long. NYSM 17001.
PLATE 13. Failleana indeterminata from the Middle Ordovician Black River Group limestones at Buck's Quarry, Poland, Herkimer County. The trilobite is somewhat disarticulated. MCZ 104928 (holotype).
PLATE 14. Illaenoides cf. /. trilobita from the Lower Silurian Rochester Shale in a commercial quarry near Middleport, Orleans County. The trilobite is 45 mm long. In the collection of Kent Smith.
PLATE 15. Illaenoides cf. /. trilobita and Dalmanites limulurus from the Lower Silurian Rochester Shale in a commercial quarry near Middleport, Orleans County. The Illaenoides species is 51 mm long. In the collection of Kent Smith.
PLATE 16. Scutellum niagarensis from drift block of the Lower Silurian Reynales Limestone in Clarendon, Orleans County. The cephalon is 17 mm long and the pygidium is 22mm long. NYSM 17023 (cephalon) and NYSM 17024 (pygidium).
PLATE 17. Scutellum senescens from the Upper Devonian Chemung beds near Avoca, Chemung County. Trilobites are rare in the Upper Devonian in New York. The specimen is about 63 mm long. NYSM 4152 (hypotype).
PLATE 18. Scutellum tullius from the Middle Devonian Tully Limestone at Borodino, Cayuga County. The illustrated cephala in A are 12 and 8mm long. PRI 49622. B. Associated pygidium of the same species. C. Reconstruction of the trilobite by Professor Wells, formerly at Cornell University.
ORDER LICHIDA
Family Lichidae
PLATE 19. Amphilichas cornutus from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. The trilobite was damaged probably during attempts to prepare it. The specimen is 36mm long. NYSM 4533 (holotype).
PLATE 20. Arctinurus boltonifrom the Lower Silurian Rochester Shale at Middleport, Niagara County. This specimen shows attached brachiopods. The trilobite is 150mm long. USNM 499453.
PLATE 21. Arctinurus boltoni from the Lower Silurian Rochester Shale in a commercial quarry near Middleport in Orleans County. This specimen shows healed damage, perhaps from a predator. The trilobite is 127 mm long. PRI 42095.
PLATE 22. Dicranopeltis nereus from the Lower Silurian Rochester Shale in a commercial quarry near Middleport in Orleans County. This trilobite is uncommon and good specimens are rare. The trilobite is 70mm long. In the Kent Smith collection.
PLATE 23. Dicranopeltis nereus from the Lower Silurian Rochester Shale in a commercial quarry near Middleport in Orleans County. This specimen shows considerable damage, perhaps by a predator. The trilobite is 59 mm long. PRI 49623.
PLATE 24. Echinolichas eriopsis from the Lower Devonian of eastern New York. NYSM 4537 (type).
PLATE 25. Hemiarges paulianus from the Middle Ordovician Bobcaygeon Formation at the Carden Quarry, Lake Simcoe area, Ontario. This small lichid is fairly common in the Kings Falls Limestone of the lower Trenton Group. The trilobite is 14 mm long. PRI 49637.
PLATE 26. A. A lichid species from the Middle Devonian Onondaga Limestone, Cheektawaga Quarry, Erie County. The pygidium is 30mm long. In the collection of Lee Tutt. B. Scutellum rochesterense (family Styginidae) from the Lower Silurian Irondequoit Limestone; exact locality is unknown. This cranidium is associated with closely packed pygidia and cranidia of Bumastus ioxus, a situation characteristic of bioherms in the Irondequoit. NYSM 17016.
PLATE 27. Cranidium of Oinochoe pustulosus from the Lower Devonian New Scotland Limestone in eastern New York. NYSM 17002.
PLATE 28. Richterarges ptyonurus from the Upper Silurian Cobleskill Limestone in Schoharie County. The figured cranidium is 7 mm long and the pygidium is 10 mm wide. NYSM 4555.
PLATE 29. Terataspis grandis from the Middle Devonian Williamsville Quarry, Erie County, in the Onondaga Limestone. This very large genal spine came from a trilobite about 580mm (23 inches) long. PRI 49638. The reconstruction drawing in the upper corner shows where this genal spine was on the trilobite and gives some idea of the scale of the complete specimen. The specimen of Eldredgeops milleri from the Middle Devonian of Arkona, Ontario, Canada, is also included for scale. The Eldredgeops is 42mm long. PRI 49639.
PLATE 30. Trochurus halli from the Lower Silurian Rochester Shale at Brockport, Monroe County. This specimen, which is missing the cranidium, is a molt 30mm long. In the collection of Paul Krohn.
PLATE 31. Trochurus hallifrom the Lower Silurian Rochester Shale in an unnamed creek in the Sodus area, Wayne County. This cranidium gives some idea of what the trilobite from Plate 30 must have looked like whole. The cranidium is 28mm wide. In the collection of Gerald Kloc.
ORDER LICHIDA
Family Odontopleuridae
PLATE 32. Diacanthaspis parvula from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This is a rare trilobite in New York, perhaps because of its small size. The specimen is 8mm long. MCZ 4372.
PLATE 33. Dicranurus elegantus from the Lower Devonian Haragan Formation in Oklahoma. This specimen is illustrated to give an idea of how the Dicranurus hamatus from the Lower Devonian of New York looked like as an articulated trilobite. The illustrated specimen is 38mm long. In the collection of Gerald Kloc.
PLATE 34. Kettneraspis callicera from the Middle Devonian Onondaga Limestone at the Benchmark Quarry, Oak Corners, Ontario County. The specimen is 26mm wide. In the collection of Gerald Kloc.
PLATE 35. Kettneraspis tuberculata from the Lower Devonian New Scotland Limestone of the Helderberg Group. The specimen is 28mm long and is found in the Blue Circle Quarry, Ravenna, Albany County. In the collection of Gerald Kloc.
PLATE 36. Kettneraspis?species, with a free cheek obviously quite different from that in the odontopleurid in Plate 35. This species is also found in the Lower Devonian New Scotland Limestone, Helderberg Group, at the Blue Circle Quarry, Ravenna, Albany County. The specimen is 18 mm across at the widest point. In the collection of Gerald Kloc.
PLATE 37. Meadowtownella trentonensis from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This is a fairly common trilobite in the quarry but is not often reported from other Trenton rocks, possibly owing to its small size. The specimen is 12mm long and shows the ventral exoskeletal anatomy. MCZ 111717.
PLATE 38. Meadowtownella trentonensis from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. A dorsal view of the same trilobite in Plate 37. MCZ.
PLATE 39. Miraspis crosota from the Upper Ordovician Frankfort Member of the Lorraine Group at Rome, Oneida County. The glabella of this partial specimen is 1 mm long. USNM 23600.
ORDER P H A C O P I D A
Family Acastidae
PLATE 40. An unidentified asteropygin from the upper Middle Devonian, Tully Limestone in Groves Creek off Cayuga Lake, Seneca County. The trilobite is 26 mm long. In the collection of Gerald Kloc.
PLATE 41. Disarticulated specimen of Bellacartwrightia calderonae from the Middle Devonian Windom Shale, Hamilton Group, Kashong Glen, Ontario County. AMNH 45273 (holotype).
PLATE 42. Bellacartwrightia jennyae from the Middle Devonian Centerfield Limestone, Hamilton Group, at Brown's Creek, Livingston County. The specimen is 38mm long. AMNH 45310 (paratype).
PLATE 43. Bellacartwrightia jennyae and Harpidella craspedota from the Middle Devonian Centerfield Limestone, Hamilton Group, at Centerfield, Ontario County. The largest Bellacartwrightia is 40mm long. NYSM 4235.
PLATE 44. Bellacartwrightia phyllocaudata from the Middle Devonian Deep Run Member, Hamilton Group, near Geneseo, Livingston County. The specimen is 34mm long. AMNH 45230 (holotype).
PLATE 45. Bellacartwrightia whiteleyi from the Middle Devonian Wanakah Member, Hamilton Group, Darien, Genesee County. The trilobite is 25 mm long. AMNH 45314 (paratype).
PLATE 46. Bellacartwrightia species from the upper Middle Devonian, Tully Limestone in Madison County. USNM 89959.
PLATE 47. Bellacartwrightia species from the Middle Devonian Windom Shale, Hamilton Group, on the Geneseo College campus, Geneseo, Livingston County. The ventral exoskeletal features of the Bellacartwrightia are shown. The specimen is 41 mm long. In the collection of James Scatterday.
PLATE 48. Bellacartwrightia species from the Middle Devonian Windom Shale, Hamilton Group, at the PennDixie Quarry, Hamburg, Erie County. The specimen is 40mm long. In the collection of Gregory Jennings.
PLATE 49. Astropyginae aff. Greenops from the Middle Devonian Pompey Member, Hamilton Group, at Rockefeller Road, Cayuga County. The specimen is 15 mm long. In the collection of Gerald Kloc.
PLATE 50. Greenops barberi from the Middle Devonian Windom Member, Hamilton Group, Buffalo Creek, Erie County. The specimen is 21 mm long. AMNH 45277 (paratype).
PLATE 51. Greenops boothi from the Middle Devonian Frame Member, Mahantango Formation, Huntington, Pennsylvania. This is the area where the original Green specimen came from and is the type area for the genus. The specimen is coiled. The cephalon is 24mm wide. YPM 35807 (neotype).
PLATE 52. Greenops grabaui from the Middle Devonian Wanakah Member, Hamilton Group, Erie County. In the collection of Fred Barber.
PLATE 53. Greenops grabauifrom the Middle Devonian Wanakah Member, Hamilton Group, Lake Erie shore, Erie County. This meraspid is 10mm long. In the collection of Kym Pocius.
PLATE 54. Greenops grabaui from the Middle Devonian Wanakah Member, Hamilton Group, Darien, Genesee County. The specimen is 24mm long. PRI 49640.
PLATE 55. Greenops species from the Middle Devonian, upper Windom Member, Hamilton Group, Groves Creek, Seneca County. The specimen is 30mm long. In the collection of Gerald Kloc.
PLATE 56. Greenops species from the Middle Devonian Kashong Shale, Hamilton Group. The specimen is 24mm long. In the collection of Gerald Kloc.
ORDER PHACOPIDA
Family Calymenidae
PLATE 57. Calymene camerata from the Upper Silurian Cobleskill Limestone at Jerusalem Hill, Herkimer County. This calymenid is distinguished by the inward curve of the anterior cheek toward the glabella. PRI 49624.
PLATE 58. Calymene niagarensis from the Lower Silurian Rochester Shale near Middleport, Orleans County. The specimen is 36mm long. NYSM 16795.
PLATE 59. Calymene niagarensis from the Lower Silurian Rochester Shale near Middleport, Orleans County. The plate is an exceptional cluster of trilobites. The largest is 34 mm long. In the collection of Gregory Jennings.
PLATE 60. Calymene platys from the Middle Devonian Onondaga Limestone in Hagersville, Ontario, Canada. This species is reported from New York. The specimen is 95 mm long. USNM 380869.
PLATE 6 1 . Calymene singularis from the Upper Silurian Oak Orchard Member of the Lockport Group. The figured cephalon is 20mm long. USNM 488139 (paratype).
PLATE 62. Calymene species from the Lower Silurian Rochester Shale on an unnamed creek near Sodus, Wayne County. The specimen is 28 mm long. In the collection of Sam Insalaco.
PLATE 63. Calymenid from the Upper Ordovician Pulaski Member, Lorraine Group, at Burke Creek, Oneida County. The latex pull figured here is very pustulose. PRI 49641.
PLATE 64. Diacalymene species from the Lower Silurian Rochester Shale at Densmore Creek, Rochester, Monroe County. The specimen, though incomplete, is strikingly different from the Rochester Shale calymenids found to the west of Rochester. The specimen is 60 mm long. NYSM 16799.
PLATE 65. Diacalymene species from the Lower Silurian Rochester Shale in Wayne County. This trilobite is different, primarily in the anterior of the cephalon, from the Diacalymene specimen in Plate 64. The specimen is 45 mm long. NYSM 16793.
PLATE 66. Flexicalymene meek/from the Upper Ordovician shales at Cincinnati, Ohio. This specimen is figured because Upper Ordovician calymenids in New York have been identified as this species. The trilobite is 55mm long. PRI 49642.
PLATE 67. Flexicalymene senaria from the Middle Ordovician limestones at Middleville, Herkimer County. The original type for this species is lost, and this specimen, figured by Hall, was chosen as the neotype. The specimen is 24.5mm long. AMNH 29474 (neotype).
PLATE 68. Flexicalymene senaria from the Middle Ordovician Poland Member of the Trenton Group at Trenton Falls, Herkimer County. This specimen is characteristic of the middle and lower Trenton F. senaria. The trilobite is 43mm long. In the collection of Gerald Kloc.
PLATE 69. Flexicalymene cf. F senaria from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry. This trilobite is somewhat different from many F. senaria specimens in that it is more pustulose and has a spinelike, acute genal angle. The specimen is 28mm long. MCZ 111710.
PLATE 70. Flexicalymene senaria from the Middle Ordovician Hillier Member of the uppermost Trenton Group in a quarry off Rte. 3 in Jefferson County. The trilobite is flattened because it was on a bedding plane, but it is apparently much less pustulose than the trilobite in Plate 69. The specimen is 28mm long. PRI 49643.
PLATE 71. Gravicalymene magnotuberculata from the Middle Ordovician Sugar River Formation, Trenton Group, North Creek, Herkimer County. Note the very differently shaped glabella compared to the one in F. senaria in Plate 70. The trilobite is 45 mm long. PRI 49644.
PLATE 72. Gravicalymene magnotuberculata from the Middle Ordovician Sugar River Formation, Trenton Group, on Allen Road, Fulton County. The ventral exoskeletal anatomy of this trilobite is shown. This is a molt as there is no sign of the hypostome. The specimen is 40mm long. PRI 49645.
PLATE 73. Liocalymene clintoni from the Lower Silurian Clinton Group, Clinton, Oneida County. Most of the Liocalymene specimens one sees are internal molds like this one. The specimen is 26mm long. PRI 49625.
ORDER PHACOPIDA
Family Cheiruridae
PLATE 74. Ceraurinella cf. C. scofieldi from the Middle Ordovician Watertown Member, Black River Group, Buck's Quarry, Poland, Herkimer County. This trilobite is usually found in the equivalent rocks in the Midwest. The cranidium is 12.5mm wide. MCZ 13.
PLATE 75. Ceraurinus marginatus from the Middle Ordovician Lindsay Formation, Trenton Group, Colborne Quarry, Colborne, Ontario, Canada. This trilobite is known from New York but is uncommon. In the collection of Kevin Brett.
PLATE 76. Ceraurus pleurexanthemus from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This specimen is 35mm long. MCZ 111708.
PLATE 77. Ceraurus pleurexanthemus from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This specimen shows the ventral exoskeletal anatomy. It is 29mm long. MCZ 111715.
PLATE 78. Ceraurus pleurexanthemus from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This specimen from inside a limestone shows a ferruginous trace along the axis, which is interpreted to be a trace of the gut. MCZ 111716.
PLATE 79. Ceraurus species from interface of the Middle and Upper Ordovician at a flooding surface between the Hillier Member of the Trenton Group and the Utica Shale on Gulf Stream, Rodman, Jefferson County. This trilobite shows differences from the more common C. pleurexanthemus. The specimen is 13mm long. NYSM 17000.
PLATE 80. Ceraurus species from the Middle Ordovician Trenton Group in a Quarry near Watertown, Jefferson County. Although similar to the specimen in Plate 79, there are differences from C. pleurexanthemus. The trilobite is 35 mm long. In the collection of Gerald Kloc.
PLATE 81. Cheirurus cf. C. niagarensis from the Lower Silurian Irondequoit Limestone in Monroe County. The cephalothorax is USNM 489751, and the pygidium, which is 23mm wide. NYSM 17022.
PLATE 82. Gabriceraurus dentatus from the Middle Ordovician Kings Falls Limestone, Trenton Group, Ingham Mills, Fulton County. This fairly three-dimensional specimen is 70mm long. In the collection of Gerald Kloc.
PLATE 83. Gabriceraurus dentatus from the Middle Ordovician Lindsay Formation, Trenton Group, Colborne Quarry, Colborne, Ontario, Canada. This specimen is 69mm long. In the collection of Kevin Brett.
PLATE 84. Cheirurids from New York for which articulated specimens are not known. A. Gabriceraurus hudsoni from the Middle Ordovician Chazy Group, Valcour Island, Clinton County. YPM 23296. B. Deiphon species from the Lower Silurian, possibly at Lockport, Niagara County. The figured glabella is 10mm wide. PRI 49626. C-E. Cerauropeltis ruedemanni from the Chazy Group limestones near Chazy, Clinton County. C. MCZ 7701. D. MCZ 1612. E. NYSM 9692 (holotype). The negatives for A and C-E were supplied by Dr. Fredrick Shaw, Lehmann University.
PLATE 85. Sphaerocoryphe robusta from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This small but interesting trilobite generally is rarely found, but a fair number were found at the Walcott-Rust Quarry, probably because of the area quarried. This specimen is 13mm long. MCZ 110901.
PLATE 86. Silicified trilobites from the Middle Ordovician Chazy Group in Clinton County. A. The cephalon (NYSM 12404) and two views of the pygidium (NYSM 12402) of Sphaerocoryphe goodnovi from Chazy. B. The cranidium (NYSM 12317), free cheek (NYSM 12325), and pygidium (NYSM 12318) of Cybeloides prima from the Crown Point Formation, Valcour Island. C. The cranidium (NYSM 12442) and pygidium (NYSM 12450) of Ceraurinella latipyga from the Crown Point Formation, Valcour Island. D. Two views of the cranidium (NYSM 12331) and one of the pygidium (NYSM 12330) of Physemataspis insularis from the Crown Point Formation, Valcour Island. The negatives for all these pictures were supplied by Dr. Fred Shaw, Lehmann University.
ORDER P H A C O P I D A
Family Dalmanitidae
PLATE 87. Dalmanites aspinosus from the Silurian Keyser Formation in Flintstone Maryland. This trilobite is also reported in New York. The pygidium is 30mm long. In the collection of Gerald Kloc.
PLATE 88. Dalmanites limulurus from the Lower Silurian Rochester Shale in Brockport, Monroe County. The actual specimen is stained red by iron minerals. It is 60mm long. In the collection of Gerald Kloc.
PLATE 89. Four specimens of Dalmanites limulurus from the Lower Silurian Rochester Shale in a commercial quarry near Middleport. Orleans County. In the collection of Kent Smith.
PLATE 90. Dalmanites pleuroptyx from the Lower Devonian Helderberg Group at Slingerlands near Clarksville, Albany County. The specimen is 60mm long. NYSM 17003.
PLATE 91. A. Dalmanites species from the Upper Silurian Lockport Group on an unnamed creek near Sodus, Wayne County. This unusual cephalon is 21 mm wide. In the collection of Gerald Kloc. B. Staurocephalus species from the Lower Silurian Rochester Shale on an unnamed creek near Sodus, Wayne County. This trilobite is rare, possibly due to the small size of the sclerites. In the collection of Gerald Kloc.
PLATE 92. Pygidium of Odontochile micrurus from the Lower Devonian at a Jerusalem Hill quarry on Albany Road, Herkimer County. PRI 49627.
PLATE 93. A cephalon and pygidium from an odontochilid from the Lower Devonian, upper Manlius Limestone, Helderberg Group, Cobleskill, Schoharie County. The cephalon is 16mm long and the pygidium is 18mm long. Both in the collection of Gerald Kloc.
ORDER PHACOPIDA
Family Encrinuridae
PLATE 94. Erratencrinurus vigilans from the Middle Ordovician at the Brechin Quarry, Brechin, Ontario. This trilobite is known from the lower Trenton Group in New York, but this is a particularly good specimen. This specimen is 14mm long. RMSC 2001.46.1.
PLATE 95. Encrinurus cf. £ raybesti from the Lower Silurian Reynales Limestone at Reynolds Basin, Orleans County. This specimen is 31 mm long. PRI 49628.
PLATE 96. A cranidium, free cheek, and pygidium of an unidentified Encrinurus species from the Upper Silurian Lockport Group in Wayne County. The figured glabella is 7 mm long. All in the collection of Gerald Kloc.
PLATE 97. Dipleura dekayi from the Kashong Shale, Hamilton Group, Livingston County. The trilobite shows healed damage to the lower right thorax, possibly due to a predator. This large trilobite is 115mm long. In the collection of Fred Barber.
PLATE 98. Dipleura dekayi from the Middle Devonian Hamilton Group, Interlaken Beach, Seneca County. This large specimen has some exoskeleton broken on the posterior thorax. The broken edges show clearly that the apparent pits on the dorsal surface actually go all the way through the exoskeleton and are holes. The cephalon is 119mm wide. PRI 49629.
PLATE 99. A Trimerus delphinocephalus and a Dalmanites limulurus together on one slab from the Lower Silurian Rochester Shale at a commercial quarry near Middleport, Orleans County. The large T. delphinocephalus is 172mm long, and D. limulurus is 60mm long. In the collection of Kent Smith.
ORDER PHACOPIDA
Family Phacopidae
PLATE 100. Eldredgeops crassituberculata from the Middle Devonian Silica Formation, Silica, Ohio. This trilobite is well known in the Midwest where this specimen was found. It is also reported from New York but is considered uncommon. This specimen is 47 mm long. PRI 49646.
PLATE 101. Eldredgeops rana from the Middle Devonian Hamilton Group in Seneca, Ontario County. This specimen has both the part and the counterpart, with the mold to the upper left. NYSM 4645 (holotype).
PLATE 102. Eldredgeops rana from the Middle Devonian Windom Member, Hamilton Group, Penn-Dixie Quarry, Hamburg, Erie County. This site is noted for the occasional finding of clusters of trilobites such as this. The Eldredgeops specimens in this cluster are relatively small, as are most of them from this site. USNM 403874.
PLATE 103. Eldredgeops rana from the Middle Devonian Wanakah Member, Hamilton Group, Darien, Genesee County. This specimen exhibits color markings in non-random patterns on the dorsal exoskeleton. These markings have been interpreted as the positions of internal muscle attachment. PRI 49647.
PLATE 104. Eldredgeops rana from the Middle Devonian Wanakah Member, Hamilton Group, Darien, Genesee County. A good view of the dorsal exoskeleton. The specimen is 22mm long. PRI 49648.
PLATE 105. Eophacops? trisulcatus from the Lower Silurian Williamson Member of the Clinton Group at Densmore Creek, Rochester, Monroe County. The preservation of exoskeletal material is poor in these rocks. USNM 79137.
PLATE 106. Eophacops? trisulcatus from the Lower Silurian Sodus Shale Member of the Clinton Group at the Genesee Gorge, Rochester, Monroe County. This is a latex mold from a not-too-good mold in shale. It does show a little more detail than Plate 105. NYSM 17041.
PLATE 107. Paciphacops loganifrom the Lower Devonian New Scotland Member of the Helderberg Group at a roadcut on Interstate 88 in Schoharie County. The specimen is 41 mm long. PRI 49649.
PLATE 108. Phacops? iowensis from the Middle Devonian Taunton Beds of the Windom Member, Hamilton Group, Livingston County. This trilobite has only been reported from the upper Windom in New York. In the collection of Steve Pavelsky.
PLATE 109. Viaphacops bombifrons from the Middle Devonian Moorehouse Member of the Onondaga Limestone in the Honeyoe Falls Quarry, Monroe County. The specimen is 24 mm wide. In the collection of Gerald Kloc.
PLATE 110. A composite plate showing the characteristics of the eyes of seven phacopid trilobites found in New York.
PLATE 111. A composite plate showing some dorsal characteristics of New York phacopids. The combination of eye structure and dorsal cephalic structure are often diagnostic to species.
ORDER PHACOPIDA
Family Pliomeridae
PLATE 112. Pliomerops canadensis from the Middle Ordovician Chazy limestones in Clinton County. Articulated trilobites are rare in the Chazy because of the high-energy conditions of these limestones. MCZ 6920.
PLATE 113. A side view of the specimen in Plate 112.
PLATE 114. Pliomerops canadensis from a reworked Chazy limestone block in the Middle Ordovician Snake Hill Shale. This pygidium shows an unusual displacement of one of the axial rings, perhaps a healed injury. In the collection of Gerald Kloc.
ORDER P H A C O P I D A
Family Pterygometopidae
PLATE 115. Achatella achates from the Middle Ordovician Trenton rocks at Trenton Falls, Herkimer County. This specimen is 21 mm long. PRI 49630.
PLATE 116. Calyptaulax callicephalus from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This specimen is 28mm long. MCZ 111712.
PLATE 117. Calyptaulax callicephalus from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This specimen shows the ventral exoskeletal anatomy of the trilobite. The specimen is 22mm long. MCZ 111713.
PLATE 118. Chasmops? bebryx from the Middle Ordovician Trenton Group at Jacksonburg, Herkimer County. This trilobite was used by Billings (1863) to illustrate the species, although he was naming a Canadian specimen. It is 39mm long. PRI 49631 (type).
PLATE 119. Eomonorachus convexus from the Middle Ordovician Glens Falls Limestone, Trenton Group, Amsterdam, Montgomery County. The holotype is reported from Trenton Falls, but it is a very uncommon trilobite in the Trenton rocks. PR I 49632.
ORDER P H A C O P I D A
Family Synphoriidae
PLATE 120. Cephalon of Anchiopella anchiops from the Lower Devonian Helderberg Group. NYSM 4262.
PLATE 121. Coronura aspectans from the Middle Devonian Onondaga Limestone at LeRoy, Genesee County. This latex cast of the external mold, or counterpart, is in better condition than the internal mold of the trilobite. The trilobite is 145mm long. NYSM 4316 (hypotype).
PLATE 122. Coronura aspectans from the Middle Devonian Moorehouse Member of the Onondaga Limestone at LeRoy, Genesee County. As one can see from the 1-cm scale bars, the cephalon and pygidium are very different sizes. Both in the collection of Gerald Kloc.
PLATE 123. Odontocephalus aegeria from the Middle Devonian Needmore Shale at Cumberland, Maryland. This same species is reported in New York. The plate is two views of the same specimen, as it is semicoiled. The trilobite is 30mm long. In the collection of Gerald Kloc.
PLATE 124. Odontocephalus bifidus from the Middle Devonian Moorehouse Member of the Onondaga Limestone at the LeRoy Quarry, LeRoy, Genesee County. The specimen is 85mm long. In the collection of Gerald Kloc.
PLATE 125. Odontocephalus selenurus from the Middle Devonian Moorehouse Member of the Onondaga Limestone at the Seneca Stone Quarry, Seneca, Seneca County. The trilobite is 41 mm long. In the collection of Gerald Kloc.
PLATE 126. Odontocephalus species from the Middle Devonian Moorehouse Member of the Onondaga Limestone in the LeRoy Quarry, LeRoy, Genesee County. There are enough differences in these specimens from the other Odontocephalus species to question whether these are of known species. The cephalon is 25mm wide. In the collection of Gerald Kloc.
PLATE 127. A. Trypaulites erinus found in a loose block, possibly Lower Devonian Bois Blanc Limestone, at Mumford, Monroe County. This pygidium is 17mm wide. B. Coronura helena from the Middle Devonian Moorehouse Member of the Onondaga Limestone. The pygidium was found in a construction excavation at Clarence, Erie County. Both in the collection of Gerald Kloc.
ORDER P R O E T I D A
Family Aulacopleuridae
PLATE 128. Harpidella craspedota from the Middle Devonian Centerfield Limestone, Hamilton Group, Browns Creek, York, Livingston County. These are small trilobites, about 15 mm long. NYSM 16798.
PLATE 129. Harpidella spinafrons from the late Middle Devonian, Tully Limestone at Moravia, Cayuga County. This specimen is 16mm long. USNM 89980.
PLATE 130. Harpidella spinafrons from the late Middle Devonian, Tully Limestone on West Brook, Sherburne, Chenango County. The original is an external mold and this is a gutta-percha cast. The longest dimension is 8 mm. USNM 516589.
PLATE 131. Harpidella species from the Middle Devonian Onondaga Limestone in the Honeoye Falls Quarry, Honeoye Falls, Monroe County. This is a previously unreported species. RMSC 2001.48.1.
PLATE 132. Maurotarion species from the Upper Silurian Lockport Group on an unnamed creek near Sodus, Wayne County. The cranidia are 5mm wide. In the collection of Gerald Kloc.
ORDER P R O E T I D A
Family Bathyuridae
PLATE 133. Bathyurus exfansfrom the Middle Ordovician Black River Group, Black River, Great Bend, Jefferson County. This specimen is 23mm long. USNM 92844.
ORDER P R O E T I D A
Family Brachymetopidae
PLATE 134. Australosutura gemmaea from the Middle Devonian Windom Member on Fall Brook, Geneseo, Livingston County. This trilobite is rare in articulated form. The specimen is 12mm long. In the collection of James Scatterday.
PLATE 135. Radnoria species from the Lower Silurian Rochester Shale. This small trilobite is usually found associated with bryozoan colonies. The specimen is 14mm long. NYSM 16792.
ORDER P R O E T I D A
Family Proetidae
PLATE 136. Coniproetus folliceps from the Middle Devonian Onondaga Limestone at LeRoy, Genesee County. This specimen is 48mm long. NYSM 4722 (lectotype).
PLATE 137. Cyphoproetus? cf. C. wilsonae from the Middle Ordovician, lower Trenton exposures at Sacketts Harbor, Jefferson County. This rare trilobite is 11.5 mm long. PR I 49633.
PLATE 138. Dechenella haldemani from the Middle Devonian Union Springs Member in Cherry Valley, Otsego County. NYSM 6489.
PLATE 139. Decoroproetus corycoeus from the Lower Silurian Rochester Shale at Brockport, Monroe County. This uncommon trilobite is 29mm long. In the collection of Tod Clements.
PLATE 140. The same specimen as in Plate 139, showing the associated ophiuroid (brittle star).
PLATE 141. Monodechenella macrocephala from the Middle Devonian Centerfield Limestone at Browns Creek, York, Livingston County. This trilobite is often found curved upward in these beds, and the two views give a good perspective on this preservation. The specimen is 29mm long. In the collection of Douglas DeRosear.
PLATE 142. Proetid from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. Proetids are very uncommon in the New York Trenton. This specimen is 11 mm long. MCZ 111714.
PLATE 143. Pseudodechenella clara from the Middle Devonian Moorehouse Member of the Onondaga Limestone, Honeoye Falls Quarry, Honeoye, Monroe County. This is a nice specimen of an uncommon trilobite. It is 31 mm long. RMSC 2001.47.1.
PLATE 144. Pseudodechenella row/from the Middle Devonian Windom Member, Hamilton Group, PennDixie Quarry, Hamburg, Erie County. Shown are two specimens with the molt remains of a third. The largest trilobite is 31 mm long. In the collection of Gregory Jennings.
PLATE 145. Pseudodechenella rowi along with Bellacartwrightia whiteleyi from the Middle Devonian Wanakah Member, Hamilton Group, Darien, Genesee County. In addition to these trilobites, one can see the pygidium of Eldredgeops rana, which shows the richness of these beds. PRI 49634.
PLATE 146. Pseudodechenella raw; from the Middle Devonian Centerfield Limestone, Hamilton Group, Bethany, Genesee County. Although this is not a close cluster, it does record an association of these trilobites before the burial event. The widest cephalon is 24 mm. In the collection of Gerald Kloc.
PLATE 147. Pseudodechenella rowi'from the upper Middle Devonian, Tully Limestone at Moravia, Cayuga County. This trilobite is recorded over a long time range in the Middle Devonian, ending with the Tully. The largest specimen is 34mm long. USNM 26767.
ORDER ASAPH I DA
Family Asaphidae
PLATE 148. ? Ectenaspis homalonotoides from the Middle Ordovician Bobcaygeon Formation, Trenton Group, in the Brechin Quarry, Brechin, Ontario, Canada. This trilobite is reported in New York but is very uncommon. In the collection of Kevin Brett.
PLATE 149. Isoteloides canalis from the Lower Ordovician Fort Cassin Formation, Crown Point, Essex County. Isoteloides canalis is the most common trilobite in these rocks, but articulated material is rare. CM 1433. The negative for this plate was supplied by Dr. Stephen Westrop, Oklahoma State Museum.
PLATE 150. Isotelus gigas from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This specimen was elected as the neotype, as the original type is lost. Isotelus gigas is characterized by the small pits abundant on the cephalon. This trilobite is 52mm long. MCZ 100938 (neotype).
PLATE 151. Isotelus gigas from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This large specimen is more characteristic of the large cephalic parts and pygidia common in the Trenton rocks. The trilobite is 122mm long. MCZ 311.
PLATE 152. Isotelus gigas from the Middle Ordovician Rust Formation, Trenton Group, at Trenton Falls, Herkimer County. Many /. gigas specimens found in museums came from one bed at Trenton Falls. This is an unusual cluster from this area. USNM 139617.
PLATE 153. Isotelus cf. /. gigas from the Middle Ordovician Grandine Member of the Neuville Formation in a quarry in Quebec City, Quebec, Canada. This is a view of the ventral exoskeletal anatomy. In the collection of Kevin Brett.
PLATE 154. Isotelus maximus from the Upper Ordovician Fort Ancient Member of the Waynesville Formation at Mount Orab, Ohio. Isotelus maximus is reported from the Upper Ordovician of New York, but this needs confirmation. This specimen is 34mm long. PRI 49650.
PLATE 155. Isotelus maximus from the Upper Ordovician at Cincinnati, Ohio. This is a ventral view of a heavily pyritized exoskeleton. The specimen is 87mm long. PRI 49651.
PLATE 156. A closer view of the pygidium from the trilobite in Plate 155. One can make out evidence of pyritized appendages on the left.
PLATE 157. Isotelus maximus from the Upper Ordovician at Cincinnati, Ohio. This molt assemblage shows the turnover of the cranidium from the molting process. The specimen is 55mm long. PRI 49652.
PLATE 158. Isotelus walcotti from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This trilobite is only reported from the Rust Formation in the immediate Trenton Falls vicinity. Although the illustrated specimen is small, one has been found at the Walcott-Rust Quarry measuring 120mm across the width of the cephalon. The specimen is 32mm long. USNM 61261a (holotype).
PLATE 159. Pseudogygites latimarginatus from the Middle/Upper Ordovician Utica Shale at Alder Creek, Oneida County. This trilobite is only found in New York in the uppermost Trenton, Hillier Member, and the Middle/Upper Ordovician transition shales. It is common in the Collingwood Shale in Ontario, Canada. This specimen is 82mm long. NYSM 17005.
ORDER ASAPHIDA
Family Remopleurididae
PLATE 160. Hypodicranotus striatulus from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This specimen prepared from inside a limestone layer shows the streamlining, suggesting that the species is free swimming. The tiny granules on the surface are not "dirt" but silica sand granules that could not be removed without causing damage. The specimen is 26mm long. MCZ 115910.
PLATE 161. Hypodicranotus striatulus from the Middle Ordovician Rust Formation, Trenton Group, Walcott-Rust Quarry, Herkimer County. This specimen was found inside limestone and reveals the remarkable hypostome, which is almost the full length of the thorax. The specimen is 26mm long. In the collection of Thomas Whiteley.
PLATE 162. Hypodicranotus striatulus from the Middle Ordovician Trenton Group at Trenton Falls, Herkimer County. This specimen from a bedding plain shows the unusual, split genal spine and the very small pygidium. PRI 49635.
ORDER ASAPHIDA Family Trinucleidae PLATE 163. Cryptolithus bellulus from the Upper Ordovician Whetstone Gulf Shale, Lorraine Group, on Burke Creek, Oneida County. The original exoskeletal material is not well preserved in these shales, but there are good external molds. This specimen does not have the long genal spine characteristic of Cryptolithus, which indicates it is a molt. Cryptolithus molted by losing the lower lamella of the ventral cephalon and exiting the exoskeleton by crawling forward. This is a latex cast from such a mold. The specimen is 8 mm long. PRI 49654.
PLATE 164. Cryptolithus lorettensis from the Middle Ordovician Sugar River Formation, Trenton Group, at Mill Creek off Rte. 3, Jefferson County. This cephalon shows the reticulation on the glabella reported for this species. The occipital spine is also nicely preserved. NYSM 17006.
PLATE 165. Cryptolithus lorettensis from the Middle Ordovician Sugar River Formation, Trenton Group, at Ingham Mills, Fulton County. Articulated specimens of the Middle Ordovician Cryptolithus are very rare, as these trilobites lived in fairly high-energy conditions and the thorax is very fragile. The specimen is a molt and is 19mm long. NYSM 17007.
PLATE 166. Cryptolithus tessellatus from the Middle Ordovician Sugar River Formation, Trenton Group, Cold Brook, Herkimer County. Although the cephala of this trilobite may be found in large numbers in beds of the Sugar River Formation, articulated specimens are rare. This trilobite is 15mm long. MCZ 921.
PLATE 167. Cryptolithus tessellatus from the Middle Ordovician Sugar River Formation, Trenton Group, at Trenton Falls, Oneida County. This plate shows the pit structure on the cephalic brim, which differentiates the Cryptolithus species. Cryptolithus tessellatus has three rows of pit immediately anterior to the cheek area. PRI 49636.
ORDER PTYCHOPARIIDA Family Glaphuridae PLATE 168. Glaphurids from the Middle Ordovician Chazy Group. A. Glaphurus pustulosus from near Chazy, Clinton County. CM 1274. B. Glaphurina lamottensis from Isle La Motte, Vermont. This trilobite is also found in the New York Chazy. In the collection of the University of Vermont Museum, specimen 2-63. The negatives for this plate were supplied by Dr. Fredrick Shaw, Lehmann University.
ORDER P T Y C H O P A R I I D A
Family Harpidae
PLATE 169. Trilobite from the family Harpidae. A. Hibbertia valcourensis from the Middle Ordovician Day Point Formation, Chazy Group, at Day Point, Clinton County. This is a rubber cast of the original external mold of the trilobite. NYSM 12293 (holotype). B. Hibbertia valcourensis from the Middle Ordovician Day Point Formation, Chazy Group, at Day Point, Clinton County. This is a rubber cast of the original external mold of the trilobite. NYSM 12292. C. Hibbertia ottawaensis from the Middle Ordovician of Canada. This trilobite is also found in New York. The figured specimen is a metal cast of the original. GSC 329 (holotype). D. Scotoharpes cassinensis from the Lower Ordovician Fort Cassin Formation, Fort Cassin Point, Vermont. This trilobite is believed to occur in New York. USNM 35817 (holotype). The negatives for A-C were supplied by Dr. Fredrick Shaw, Lehmann University. The negative for D was supplied by Dr. Stephen Westrop, Oklahoma State Museum.
ORDER P T Y C H O P A R I I D A
Family Olenidae
PLATE 170. Triarthrus beckii from the Middle Ordovician Utica Shale at Dolgeville, Herkimer County. This specimen shows the yoked, connected, free cheeks of this trilobite. They are slightly displaced here. In the collection of Fred Wessman.
PLATE 171. Triarthrus cf. T. eatonifrom the Upper Ordovician Whetstone Gulf Member, Lorraine Group, on Burke Creek, Oneida County. This specimen is unusual in that there are no axial nodes on the anterior thoracic segments. The specimen is 21 mm long. PRI 49655.
PLATE 172. Tharthrus eatoni from the Upper Ordovician Frankfort Member, Lorraine Group, on Six Mile Creek north of Rome, Oneida County. This specimen is from the world renowned Beecher Trilobite Bed, which is the most prolific known source of trilobites with appendage information. This trilobite is 40mm long. YPM 228.
PLATE 173. Triarthrus spinosus from the Upper Ordovician Utica Shale on Nine Mile Creek, Oneida County. This is a rare trilobite in New York but is often found in Canada. The width across the posterior aspect of the cephalon is 15mm. USNM 96235 (holotype).
PLATE 174. Triarthrus spinosus from the Upper Ordovician at Ottawa, Ontario, Canada. This specimen shows the characteristic genal spines and thoracic spines of the species. The trilobite is 15mm long. In the collection of Kevin Brett.
ORDERS ASAPHIDA A N D PTYCHOPARIIDA
Families Saukiidae, Idahoiidae, Plethopeltidae
PLATE 175. Trilobites from the Middle Cambrian limestones of New York. A. Prosaukia hartti from the Hoyt Limestone, Greenfield railroad cut, Saratoga County. NYSM 14079. B. Saratogia calcifera from the Hoyt Limestone in the Hoyt Quarry at Lester Park, Saratoga County. NYSM 14081. C. Plethopeltis saratogensis from the Briarcliff Dolostone at Poughkeepsie, Dutchess County. NYSM 14147. The negatives for A and B were supplied by Dr. Stephen Westrop, Oklahoma State Museum.
"Paleontologists both young and old will enjoy
"Thomas E. Whiteley is a research chemist re-
this book. Trilobites of New York is a wonderfully
tired from the photographic industry, Gerald J.
illustrated book that all fossil collectors will rel-
Kloc is a nationally known preparator of fossils,
ish. The authors combine a thorough review of
and Carlton E. Brett is a professor of geology
the natural history of trilobites with taxonomic
who has looked at almost every outcrop of sedi-
descriptions, photographs, and occurrence data.
mentary rock in New York State; together they
The photography is superb, and the plates will
have produced a book that should be a broad
be the envy of many paleontologists."
path for other amateurs and professionals to follow. Trilobites of New York has the charm of an
— T i m White, Senior Collection Manager,
artistic portfolio and the fullness of the rigors of
Division of Invertebrate Paleontology, Peabody
systematic stratigraphy and paleontology. This
Museum of Natural History, Yale University
book will be used extensively by the teachers of New York, it will be eagerly sought after by amateur collectors, and for good reason will be used by college professors teaching paleontology to undergraduates around the world." —Fred Collier, Curatorial Associate in the Department of Invertebrate Paleontology, Museum of Comparative Zoology, Harvard University
Published in cooperation with the Paleontological Research Institution, Ithaca, New York A Comstock Book
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