Similarity Problem
10. The Kadison
Summary: This chapter concentrates on the (still open) Kadison Similarity problem (...
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Similarity Problem
10. The Kadison
Summary: This chapter concentrates on the (still open) Kadison Similarity problem (= Problem 0.2). We show that this problem is equivalent to several seemingly different questions which appeared in other contexts: Arveson's hyperreflexivity problem and Dixmier's invariant opemtor range problem. Finally, we describe the author's recent work on the notion of "length" of an opemtor algebm, which also leads to one more reformulation of Kadison's question.
general form, the Kadison similarity problem asks whether any bounded homomorphism u from a C*-algebra A into B(H) is similar to a homomorphism (= "orthogonalizable"). This is the same as Problem 0.2 from the introduction. Indeed, this can be In its most
reduced to the unital
Recall first how ideal in
A
and if
A and A in C
follows.
C*-algebra
is the unit in
e
we
case as
a
A is embedded into its unitization
A
we
A + Ce,
Ila + AeJJX
<
1Ilall, JAI
2
any bounded
homomorphism
u:
A
--+
B(H)
JAI
can
B (H) by setting ii(a + \e) homomorphism ii: , orthogonalizable, u (being its restriction to A) also --
Remark. With the
passing that
Ilull
> 1
if
Also since
a
preceding notation,
since A has
u: 0, + Ae
moreover
A is
for any
a
an
in
have
max
Thus,
have
A:
hence -
an
lliill
A is
a
we
have
Ilall.
be extended to
u(a)
+ AL
a
bounded
Clearly,
if ii is
is.
Ilull
<
lliill
in its unit ball
approximate unit :5
=
+
:5
21jull
we
+ 1. Note in
have
necessarily
31jull.
*-homomorphism
it is
completely contractive,
from
which it is easy to deduce that
IJUIlcb :5 lliillcb ::_ 21julIcb Thus
we
have
proved
lem reduces to the unital
Quite curiously,
that the above
+ I <
general
31julIcb-
formulation of Kadison's
the Kadison
probEl
case.
problem
turns out to be
equivalent
to
a
number
of questions which come up in various different contexts and which make its solution even more desirable. We have already seen one such equivalence:
10. The Kadison
Theorem 10.1.
derivation
The Kadison
problem (=
This is due to the end of
Problem
Similarity
similarity problem (= 0.2) are equivalent.
Kirchberg [Ki]. We have included
Problem
detailed
a
Problem
0.2)
169
and the
proof above,
at
7.
equivalent form of the preceding problem which arose algebras". This is a certain class of non-selfadjoint subalgebras of B(H), of which the simplest example is the algebra of upper triangular matrices in M,, or in B(H). More precisely, a nest on a Hilbert space H is a family C of subspaces of H, totally ordered under inclusion and such that for any subfamily (Ei)iE, in C we have We
turn to
now
in Arveson's
theory
an
of "nest
nEi
EC
UEjEC.
and
iEI
iEI
Given such
a
nest
all operators T in
C,
one
T(E)
V E (=- C The
subalgebra A(C)
associates to it the
c
B(H)
formed of
such that
B(H)
C E.
resulting algebras are called "nest algebras". For instance, the algebra of triangular matrices in M,, corresponds to the nest (Ei, 1 < i < n) defined
upper
by Ei
=
span[el.... ei],
(ei) denotes the canonical basis of fn2. These algebras were introduced by Ringrose, motivated by Kadison and Singer's earlier work on "triangular algebras". We refer the reader to [Dad] for a detailed exposition of this subject. The most striking result of this theory is probably Arveson's distance formula which we will now explain (this was briefly mentioned in the Notes at the end of 4). Let A c B(H) be a subalgebra, we denote by Lat (A) the set of all closed where
subspaces
E C H which
operator T in
B(H)
we
are
A-invariant
d(T, A) Then it is easy to
see
-
an
equality, namely
supf 11 (1
(10.2) This led him to an
algebra
=
inff JIT
-
-
PE)TPE I I
PE)TPEII I
The basic result of Arveson's
becomes
a
in
A).
Given
an
all I
<
a
E
Al.
subspace
E
we
have
d(T, A),
B(H)
supf 11 (1
(10.1)
aE C E for all
that for any A-invariant
I (I whence for any T in
(i.e.
set
study
-
theory
E
c
Lat(A)J
<
is that if A is
for any T in
PE)TPE 111
B(H)
E E
we
a
this distance formula for
nest
algebra then (10.1)
have
Lat(A) I
is called "reflexive" if it satisfies the
d(T, A).
=
d(T, A).
general classes implication
more
of
algebras:
Similarity Problem
10. The Kadison
170
it is called T in
VE c
c E
(T(E)
if
"hyperreflexive"
Lat(A)) there is
moreover
=#-
T c-
A;
constant K such that for any
a
B(H) d(T, A)
KsupJJJ(1
-.5
-
PE)TP-pil I
Lat(A)J.
E E
1 for nest algebras. The first examples hyperreflexive algebras were given by Kraus and Larson [KrL]. These are not selfadjoint. In the selfadjoint case, von Neumann's bicommutant theorem implies that every von Neumann algebra is reflexive. The problem whether they are hyperreflexive was raised by Arveson in [Ar2] and has
As
just
we
saw, this holds with K
=
of reflexive but not
remained open since: Problem 10.2. Is every
Neumann
von
Theorem 10.3. Kadison's mann
problem hyperreflexive.
is
algebra
Proof: We have
already
M is inner, then M' is
is
us now a
<
von
KsupJJJ(I
where the supremum runs A fortiori, if we let 6T(X)
over
=
d(T,M) a
check the
fortiori
we
:5
xT
-
B(H)
M c
and any T in
P)TP111:5 KsupJJJTP
-
PT111
all projections P in M'. Tx, we find -
<
1i
x
E
M11.
have
when
ir:
A
case we
--*
B(H)
may
M
=
as
is
well
A' in
an
isometric
assume
(10.3)
we
J6T11cb(A,B(H))
embedding
that A c
obtain, !
a
B(H)
can
(v), but restricted to the a C*-algebra A. Indeed,
of
and
fortiori, for
4KI16T: A"
--+
exchange the roles of
ir
is the inclusion map.
any T in
B(H)
B(H)11.
But since the unit ball of A is dense in that of A" in the weak operator
find
116T: A" and
we
(10.4)
we
116TIleb,.5 4KI16TIl
Then, taking
we
algebra
Assume that every M argument, we find a universal
for any inner derivation 6T: M' -+ B(H). Since we M' and M, we obtain the situation of Theorem 7.21 in that
Neumann
Neu-
M and its commutant,
algebra
2KSUPJJJ6T(X)JJ I JJXJJ
(10.3)
case
von
converse.
sum
Neumann
on a von
every
have
d(T, M)
whence
positive solution iff
simple direct
constant K such that for any we
a
hyperreflexive. Exchanging
only hyperreflexive. Then, by
B(H)
has
that if every derivation
seen
if part. Let
obtain the
algebra hyperreflexive?
--+
B(H)11
=
116T:
A
obtain
116T116:5 4KI16TIl
-4
B(H)11
topology
10. The Kadison
for any 7r-inner 6T: A
--*
B(H).
Similarity Problem
complete the proof,
To
it remains
that the assumption that 7r: A --+ B(H) is isometric is very easy: given a fixed inclusion A C B(h) and a a:
A
a
0
0
a(a )
)
representation (=*-homomorphism)
7r(a) This is 0
an
0)
isometric
we
can
to show
only
be removed. This
(possibly
not
faithful)
consider
--+
B(H,)
we
E
B (H ED
H,).
any T in B (H,), if
representation and for
171
we
let 0
have
T
0
0
ir(a)O
07r(a)
-
=
0
(0 o,(a)T-To,(a))
which shows that
16TIl
=
and
11boll
116T116
=
116011cb.
(10.4) holds for a faithful 7r, it also holds if 7r is replaced by an arbitrary representation (=*-homomorphism) a. Thus we obtain the condition (v) in Theorem 7.21 for any C*-algebra A, which is equivalent to the Kadison 11 problem. We now turn to a topic which was in vogue many years ago, namely "operator ranges". An operator range is a linear subspace V of a Hilbert space H which is the range of bounded operator T: H --> H, i.e. we have V T(H). Typically we will be dealing with subspaces which are not closed, and Foias introduced the term "paraclosed subspaces" to designate operator ranges. In the early 70's, this subject was studied by several authors, among whom Fbias [Foi2], Fillmore and Williams [FiW] and Voiculescu [Vo]. The following problem, due to Dixmier, (whose 1949 thesis is devoted to a related topic) has circulated for a long time: This shows that if
=
invariant operator range problem.) Let V C H be an B(H) be a unital C*-algebra. Assume that V is
(The
Problem 10.4.
operator range and let A C invariant under
A'
(=
Dixmier, whom in
a
aV C V for any
A, meaning
the commutant of A) such that I
consulted, kindly
letter addressed to
von
find another operator
T
wrote
me
in A. Is there
an
operator T in
V?
back that he asked this question
Neumann in 1950.
T(H)
Remark. Of course, if V problem is to show that if V =
T(H)
a
=
=
and
T(H)
in A' with the
that V is not assumed closed
T
E
A' then V is invariant under A. The
is invariant with T E
B(H),
then
we can
range. Again, we should emphasize the solution is trivial: we can take
same
(otherwise,
T the orthogonal projection onto V which clearly is in A' if V is closed and invariant). Following an idea of Foias ([Foi2]) we will show that this problem is equivalent
for
to the Kadison
one.
10. The Kadison
172
Proof: a
problem (= Problem 10.4) has a similarity problem (= Problem 10.2) also does.
The invariant operator range
Theorem 10.5.
solution iff the Kadison
positive
Problem
Similarity
Following [Foi2], we will associate to an invariant operator homomorphism. u: A -- B(H). So we assume V
bounded unital
C*-subalgebra. injective. Fix
Let K
A and k
a
E
T(H)
with
C
=
=
Ilk. By the
that aTk
=
V for any a in A where A c B(H) is a unital V and of course TIK is ker(T)J-. Note that T(K)
such that aV
B(H)
T E
range V C H
aT(K)
K. Since closed
c
T(K)
a unique k in K such correspondence k --+ i defines
there is
the
graph theorem,
bounded linear operator which we denote by u(a). It is easy to check that u(a) e B(K) is a unital homomorphism. Moreover, one more application of the closed graph theorem shows that a --* u(a) is bounded. Thus we obtain the a
a
--+
announced
homomorphism. associated
u(a))
Tu(a),
aT
=
hence if 0
to V. Note that
K
TIK:
=
u(a)
VaE,A but in this formula
Then there is
an
0-1 is we
H
--+
Now
S-'ir(a)S
=
(by
have
definition of
0-'aO
=
K such that
have 0-'aO
we
have
we
priori unbounded.
invertible S: K Thus
homomorphism.
a
--+
assume u -+
a
7r(a)
orthogonalizable.
Su(a)S-'
=
and if we let
x
=
is
a
OS-': K
x7r(a) ax for any a in A. But since A is a C*-algebra and 7r(a*) x7r(a)* x7r(a*) a*x, hence taking adjoints lr(a)x* x*a, and 7r(a)*, xx*a. But we can also write finally (after left multiplication by x) x7r(a)x* H
we
have
=
have
we
=
=
=
=
x7r(a)x* Thus
the x
we
have
(x7r(a))x*
xx*: H
proved that
(xx*)'I'.
for
same
=
=
(ax)x*
=
axx*.
A, which implies polar decomposition of
H is in the commutant
--+
A moment of
thought
on
the
shows that
T(H) and since
x
=
OS-' with S invertible
x(K) Thus
we
We have thus shown that lem 10.4.
Conversely,
u:
A
-+
a
=
=
have
T(H).
.
.
.
be
a
bounded unital
notation. Let
(6,,)
B(H,,)
-+
be
u(A) j
T
c
A'.
a
one
to Prob-
+
homomorphism. Assume H separable H, and let H,, C H
dense sequence in +
u(A) ,.
defined by u.,,(a) hence, by Theorem 7. 11,
B(H.,,) set
,
able. Whence S,,: H,, -4
with
positive answer to Problem 0.2 implies positive answer to Problem 10.4.
homomorphism u,,: A ,, as cyclic 1,
admits
A
O(K)
T(H)
H,,
7r,,:
clearly
assume a
B(H)
simplicity of be defined by
for
The
we
x(K)
conclude V
Let
=
=
H,, invertible (and bounded) and
such that
u,,(.)
=
S,-,1,7r,,(-)S.,,.
u(a)IH,,, obviously
=
u,, a
is orthogonaliz*-homomorphism
We may
as
well
assume
10. The Kadison
JIS,,11
1. Let
B(ft)
ii: A
Hi 6) H2 (D
be defined
We have
(a)
is
1,
=
S-' (a),
:
F1
Problem
`R: A
B
--
173
(ft)
and
by
EDS,
=
and let
...
Similarity
(a)
injective,
where here
ax,,(a)
=
its
-1
and
i (a)
u,,(a).
=
r( )
is invariant under
image
and
have
we
priori unbounded. Suppose for a moment that we can show that i is orthogonalizable. Then it is easy to see that u itself must be orthogonalizable. Indeed, we have 11U11cb IP16 hence SUP JIU,,Ilcb u is orthogonalizable by Corollary 4.4 (one can also prove it directly). Thus to complete the proof it suffices to show that any homomorphism u: A B(H) of the form u(a) H bounded, injective and with 0-17r(a)0 with 0: H V O(H) invariant under 7r(A), is orthogonalizable. If we assume a positive solution to Problem 10.4, this is easy: we can find 0 in 7r(A)' such that O(H) V. Let Ho (ker0)_L. Note that Ho is invariant =
is
a
=
=
--+
--+
=
=
_
=
=
7r(A). 7r(a)Oo
under
Let
have
=
Oo: Ho
--+
0o7r(a)jH,,
H be the restriction of 0 to
for any
a
7r(a) But V
=
O(H)
=
0-10o7r(a)IH000
W(H)
10.
But
in A
=
hence,
on
Ho which is injective. We 00 we have
the range of
Oo7r(a)IHOOO 1.
is also the range of 00. Hence we have now 00 10: H -* Ho and 0-100: Ho
u(a) ---
=
H
0-17F(a)O
are
bounded
by the closed graph theorem (note here that, of course, Ho is closed), hence u is orthogonalizable. This completes the proof that "yes" to Problem 10.4 implies 11 44yes" to Problem 0.2. Remark. Note that
we
may
as
well
assume
in Problem 10.4 that A is
a von
already know this for Problem 0.2 (by passing bidual). See [On] for more details on this particular point. mann
algebra,
since
The results in for the
(SP)
Chapter 4, and notably Theorem 4.3 provide ample
Neu-
to the
motivation
following:
Generalized the
we
Similarity
Problem.
following property (SP) For any H, every bounded
Which unital operator
algebras A have
?
unital
homomorphism
u:
A
--+
B (H) is
c.
b.
Loosely speaking, this property (SP) could be described as "automatic complete boundedness" in analogy with the field of automatic continuity for homomorphisms between Banach algebras (see [DW]). The Kadison problem is equivalent to showing that every C*-algebra satisfies
(SP). [P9],
In
for
an
show that this property (SP) is closely linked to a notion of "length" operator algebra. Related results appear in [P10-11-12]. The rest of this we
chapter The
is
an
outline of all these results.
"length"
that
we
have in mind is
analogous
to the
following
situation:
a unital semi-group S and a unital generating subset B C S, it is natural to say that B generates S with length < d if any x in S can be written as
consider
a
product
x
=
b1b2
...
bd with each bi in B. Our main idea
can
be illustrated
10. The Kadison
174
in
Similarity Problem
rather transparent way
a
simple model of semi-groups
the above
on
fol-
as
lows. Assume that B generates S with length < d. Then any homomorphism 7r: S -- B(H) (i.e. 7r(st) 7r(s)-7r(t) and 7r(l) 1) which is bounded on B with =
=
sup
11-7r(b) 11
be bounded
< c must
11 7r(s) 11A
the whole of S with sup
on
SES
bEB
Conversely, assume that we know that morphisms ir: S -- B(H) satisfy, for some sup
11 7r (b) 11
:5
c =:>.
for
sup
11 7r (s) I
<
n
>
0, all homo-
following implication:
> 1, the
c
and
> 0
some a
rw'.
SES
bEB
Then it is rather easy to see that B (=integral part of a), so that we can
necessarily generates S with length replace a by [a] and r, by 1.
<
[a]
Definition. An operator algebra A C B(H) is said to be of length < d if there is a constant K such that, for any n and any x in Mn (A), there is an integer N =
ad-1 E MN(C)i N(n, x) and scalar matrices ao E Mn,N(C), al E MN(O)) in MN(A) satisfying ad E MN,n(O) together with diagonal matrices Dj,..., Dd -
-
.,
I
x
=
aoDlaID2... Ddad
d
d
fj Had 11 IlDill We denote of A
(so
KlIxII.
the smallest d for which this holds and
by t(A)
that A has
Equivalently,
<
1
0
length
<
d is indeed the
may reformulate this
we
same as
we
t(A)
using infinite
:!5
usual
k(A)
=
Mn(A) UM,,(A)
c
Mn+,(A)
be the
via the
mapping
completion of the
the norm, then it is easy to check that
f(A)
x
--+
"length"
d). if
matrices:
we
view
0
(0 0), X
as
call it the
and if
we
let
union with the natural extension of <
d iff any
x
in
IC(A)
can
be written
as x
=
aODjaj
with ai in K(C) and Di diagonal in by the open mapping theorem.) We start with
Proposition
an
...
Ddad
IC(A). (The
constant K
automatically
exists
easy observation.
10.6. Assume
We have then for any
f(A)
=
d <
homomorphism
oo
with
d, K
.1rom A to
u
as
in the above definition.
B(H)
JIU116:5 KIJUIld. Proof: Consider
x
in
M,,(A).
Let u,,:
M,,(A)
-+
M,,(B(H))
denote the usual
SUP111un 111 n > 11. Let homomorphism (= 10 u). Recall IJUlIcb unit ball of M,,(A). Consider a factorization of the above form: =
x
with ai "scalar" and Di
=
aoD,
"diagonal".
...
Ddad
We have then
x
be in the
10. The Kadison
Un(X)
aOUN(Dl)al
...
Similarity
Problem
175
UN(Dd)ad
hence
11Un(x)11 but
clearly
since the
Di's
are
diagonal JJUN(Di)JJ
HUnW11 which
yields (recalling
the
fl 11aill 11 JJUN(Di)JJ
:5
<
11ull IlDill
hence
11ulld H 11aill fl IlDill
:5
meaning of t(A)
d)
<
JJU116:5 K11U11d. El
The main result concerning this sufficient for (SP), it is also necessary: Theorem 10.7. A unital operator over, let
d(A) (here
of course
u
=
infla
denotes
an
algebra A
13
> 0
"length"
K V
satisfies
t(A)
(SP)
<
00
is not
iff t(A) <
oo.
only
More-
1JU116:5 KilullI
u
unital
arbitrary
is that
homomorphism from A
to
B(H)),
then
d(A) and the infimum
defining d(A)
We refer the reader to
[P91
=
t(A)
is attained. or
[P16]
for the
proof C*-algebra, let us momentaxily some K, all bounded (not necB(H) satisfy IJUIleb < Kilulld. By the
Remark. If A is any (not necessarily unital) denote by do(A) the smallest d such that, for
essarily unital)'homomorphisms u: A -+ remark on A which opens this chapter, it is easy to check that do(A) d(.X). On the other hand, we have (this is a particularly easy case of (10.6) below) f(A) (A). Thus (by Theorem 10.7) we obtain the equality do(A) f(A) for any C*-algebra A. A C (as unital C*-algebras) hence Now, if A happens to be unital, then clearly d(A) d(A). Thus we have do(A) d(A) in this case. Therefore, there is no need to distinguish do(A) and d(A), at least when A is a C*-algebra, so that from now on we set d(A) do (A) for any C*-algebra (unital or not). Thus we can now write d(A) t(A) for any C*-algebra A. Remark 10.8. Let us briefly return to the derivation problem. By Theorem =
=
=
=
=
=
=
7.21 and
(7.26)*,
if
we
have
11611cb
(10.4) for all
7r
and all 7r-derivations 6: A
of
a.
u as
in Theorem 10.7. Therefore
This leads
us
to
a
conjecture
:
a11611
B(H)
JJUJJcb
(10.5) for all
-+
<
<
then
we
have
HU11a
t(A)
is less
or
equal
to the
integral part
Similarity Problem
10. The Kadison
176
Conjecture. For any infinite dimensional C*-algebra A, the best possible (10.4) is always an integer. Let KA be the best K such that:
V
:5 K IlUlld(A). We have
IJUJIcb
u
example of an infinite dimensional C*-algebra A for which KA a
a
But
> 1.
we
in
no
have
suspect:
Conjecture. If A
B (E2) E)
=
too then KA
(here d(A)
> 1
It is easy to see that the property (SP) passes to if I c A is a closed two-sided ideal then
f(AII) and also that f (A) :5
maxjt(I), f(AII)}. f(A)
(10.6) To show
there is
in I
x
aai
particular,
aia
-
Let
(i) (ii)
(D
...
of infinite direct
us now
Kadison
-4
below).
quotients. More precisely,
t(A)
If A is
a
C*-algebra,
we
have
maxf (I), f(A/I)}.
ED
&
.
A,,,)
sums
review the
have xai -+ a in A.
we
and aix
x
x
--+
and
moreover
0 for any
for all finite sets
t(Ai case
see
: (A) we merely use the fact (due to Arveson, see [Wa]) that "quasi-central approximate unit" in I, i.e. a net (ai) in the unit ball
(quasi-centrality)
The
=
3,
t(I)
a
of I such that for any In
<
=
.
=
.
,
A,, of operator algebras
maxjt(Ai) 11
is discussed in
cases
for which
a
< i <
we
have
nf.
[P12].
positive solution
is known for the
problem:
A is commutative.
C*-algebra, denoted by K, of all compact operators on t2, or its unitization, denoted by k. More generally, by Theorem 7.16, A can be any nuclear C*-algebra. (iii) A B(H) or more generally A can be any C*-algebra without tracial. states, see Corollary 7.14 above. IC 0 B with B an arbitrary C*-algebra (here again A has no tracial (iv) A A is either the
=
=
states)(V)
A is
a
Hi-factor with Murray and
for instance when A is the so-called
product We will
preceding
of 2
2 matrices with normalized
trace).
give the degree (=length) of the algebras appearing in'the 1, so from now dim(A) < oo, we have clearly d(A)
now
list. When 1 <
on we assume
(i) (ii) (iii) (iv)
x
Neumann's property F (see [C4]) hyperfinite III-factor (= infinite tensor von
dim(A)
If A is commutative, If A
=
If A
=
If A
=
IC, A
=
B(H), k (9 B
k
or
then
=
oo.
=
d(A)
if A is
d(A)
with B
arbitrary C*-algebra )
=
=
2.
nuclear, also d(A)
=
2.
3.
arbitrary unital C*-algebra (or then 2 <
d(A)
< 3.
if A
=
IC 0 B with B
10. The Kadison
If A is
(v)
< 3 is
(ii)
and
(i)
Notes:
Hi-factor with property P then d(A)
a
are
=
Similarity
Problem
177
3.
(see [C2]).
due to J. Bunce and E. Christensen
(iii)
In
proved in [Hl] while > 3 is proved in [P9] (see below for more on this). essentially in [111]. Finally, concerning (v), Christensen proves in [C4] that
(iv) is d(A) < 44,
but this bound is reduced to < 5 in
[P12],
d(A)
and
:! 3 appears in
the very recent preprint [C8J. It is also mentioned in [P12] that (as pointed out by N. Ozawa) Anderson's construction in [And] remains valid on any 11, factor,
yielding d(A) > 3 for any II, factor A by the same argument as in [P9]. sharp contrast, the conjecture is still open when A is the reduced C*-algebra
thus In
of the free group with > 2 generators,
EX
M=
or even
when A
M with
=
=fx=(X,,)Jx,,EM,, SUPIIX,,11<001.
n>1 00
C*-algebra f,,o (IN; M) (formed of all bounded famcounterexample to the Kadison conjecture. The evidence for this lies in the following result from [P12] and its corollary: we feel the property appearing in this corollary is "too strong to be true" but unfortunately we
We
strongly suspect
(Xi)iE]N
ilies
M)
in
that the
is
a
cannot prove this!
Proposition 10.9. Let A be an operator algebra. following assertions are equivalent.
(i) Welave (ii) There is
(IN, A))
an
integer d
> 1.
The
d.
<
that, for
constant K such
a
Fix
any n, there is
an
integer N
=
N(n)
and scalar matrices of norm 1
Mn,N (0)
aO G
such that for any
,
x
MN (C))
al E
in
Mn(A)
...
there
i
ad- 1 E
are
MN (C)
diagonal
7
ad G
matrices
MN,n M Dl,..., Dd
in
d
rl I I Di 11
MN (A) with
:5 K I I x I I and satisfying
1
x
CorollarylO.10. then there is
a
=
aoDlalD2... Ddad.
If the C* -algebra
(IN; M)
constant K such that for any
satisfies the Kadison conjecture, there is an integer N N(n)
n
=
and scalar matrices of norm I aO E
such
Mn,N (C)
that, for
any
,
al E
integer
MN (0)
m
and any
ad- 1 E
x
MN (C)
,
ad E
in the unit ball of
MN,n M
Mn(M,,)
there
are
d
diagonal
matrices
Dl,..., Dd
in
MN (M,,,) with
rl 11 Dill
:5 K and satisfying
1
x
The class of
algebras
that of "amenable Banach
=
with
aoDlalD2
...
Ddad-
d(A)(= f(A)) equal to 2 is closely related to e.g. [M]). A von Neumann algebra
algebras" (see
10. The Kadison
178
M C
with a
B(7i) JJPJJ
Similarity
is called amenable
=
Problem
(= injective)
if there is a projection P: B(H) M deep paper [Co], it is known (see [CE]) that amenable, see [H7]) iff for every representation B(H), the von Neumann algebra M, 7r(A)" injective). This motivates the following --+
1. Thanks to Connes'
C*-algebra A
is nuclear
(= *-homomorphism)
(,
A
7r:
=
generated by,7r
is amenable
Definition. A
C*-algebra is called semi-nuclear if for any representation,7r: A von Neumann algebra 7r (A)", the generated alge-
B(H) generating a semi-finite bra ir(A)" is injective. Theorem 10.11.
([P9])
For
C*-algebra A, d(A)
a
< 2
implies that A
is semi-
nuclear. It is
an
problem whether
open
if A is either the reduced
or
A nuclear
general semi-nuclear =: , nuclear. However, C*-algebra of a discrete group G, then
in
the full
A semi-nuclear
#:
-*
G amenable.
The preceding result shows that d(B(H)) > 2, since otherwise B(H) would semi-nuclear, which contradicts the main result in [And]. Hence, we have d(B(H)) > 3. Actually, using the length t(B(H)) instead, we can obtain a very simple proof that d(B(H)) 3, as follows. Proof that (B(H)) < 3: This very direct proof comes from [P12]. Fix n > 1. Let W, and W2 be any two n x n unitary matrices such that be
=
V i,j
JW2(iii)l
JW1(iJ)J
Note that there
are
associated to the
examples
many
of such
(suitably normalized)
n- 1/2
:=
matrices, for. instance the
Fourier transform
on
group of order
there
are
matrix
any commutative
n. Then, for any x in the unit ball of Mn (B (H)) (with dim H diagonal matrices D1, D2, D3 also in the unit ball of Mn (B (H))
=
00)
such
that x
The
proof of this orthogonal ranges
is very so
=
DlWlD2W2D3-
simple. Let Si,
i
1,
=
.
.
.
,
n
be isometries
on
H with
that
V iJ
Si*Si
=
6ii I
-
Then let
D, (i, i) and
=
Si*
and
D3
Sj
moreover
D2 (k, k)
=
n
7 W, (i, k) Sixij Sj* W2 (k, ij
The announced properties
are now
but
a
simple verification.
El
10. The Kadison
Similarity Problem
179
Proposition 10.12. The Kadison similarity problem has a positive answer for all unital C*-algebras A iff there is an integer do such that (A) :! do for any C*-algebra A. By Proposition 10.6, if we have a bound for the length, the Kadison conjecture is immediate. Conversely, if there are C*-algebras Ad with length tending to infinity with d, then clearly the length of their direct sum (in the f,, sense) must be infinite, so this direct sum must fail the Kadison conjecture. El Unfortunately, up to now, the highest known value of t(A) for a C*-algebra is 3, but we conjecture that there are examples of arbitrarily large length. However, in the non-self-adjoint case, we have recently been able to prove the following. Prooh
Theorem 10.13. For any integer d > operator algebra Ad such that
i(Ad)
1, there
=
is
a
(non-self-adjoint)
unital
d.
algebras with arbitrarily large finite length? example with 2 < t(A) < oo is known. However, algebras is proved in [P9] that any proper uniform algebra A must satisfy t(A) > 2. It also unknown whether there are Q-algebras (= quotients of uniform algebras)
Problem. Are there uniform For uniform
with 2 <
t(A)
<
no
it is
A
oo.
Remark.The above similarity problems are also intimately connected to several perturbation problems for von Neumann algebras posed in the 70's by Kadison and Kastler
[KK],
as
follows.
M, N be two von Neumann algebras in B (H). Let d(M, N) denote their Hausdorff distance, and suppose d(M, N) < c (this means that any point of the unit ball of M is at distance < c from some point in the unit ball of N, and vice versa). The Kadison-Kastler problem can then be stated like this: if c > 0 I < 6 (6) is small enough, does there exist a unitary U in B (H) such that U ? N U*MU that with 6(E) --* 0 when e 0, and such A positive solution to the Kadison problem (Problem 0.2) would almost surely allow a breakthrough on this problem too. Indeed, there are some important contributions of E. Christensen ([C5, C6, C7], see also [Ph]) showing that, under be solved some supplementary assumptions, the Kadison-Kastler problem can Kadison the N problem. for von Neumann algebras M, verifying Let
-
=
--
Note in
particular, that
d(M,, (M), M,, (N))
if both
rather
well,
t(M) we
<
oo
find for
and
t(N)
some
< oo,
then
we can
estimate
constant C:
supfd(M,,(M),M,,(N)) Jn>1J
length generated by
to the closed
convex
is
a
hull of the union
U34=lCj
where
10. The Kadison
180
Cj
Assuming
=
Similarity Problem
jX1X2
that this
another Banach
holds, algebra 0.
let
...
u:
Xj
I
B
F-+
Xk E C
Vk
0 be
a
continuous
homomorphism
into
It is then easy to check that d
Ilull
:5 K
E MaXIIIUIB1 Ili IIUjB2 11 jj j=1
where K is
Thus if
a
(depending only
constant
and
B,,3
all unital
u are
Ilull In the
:5
we
on
obtain
d and the size of the subset
(since
all the
C).
norms are now >
1)
dKMaXfIIUIB, Ili IJUIB2 111d.
direction, assuming again B1, B2 and B all unital, let algebra generated by B, and B2, which we assume is alg(Bl, B2) dense in B. Assume that every unital homomorphism u: alg(BI, B2) --+ 3 into an arbitrary unital Banach algebra 13 such that IIUIB1 11 < oo and IIUJB2 11 < C)O is bounded and satisfies actually converse
denote the
Ilull where K and
<
K(maxf IIUIB, 11) IIUJB2 11 J)C'
independent of u and 3. (see [P9, 8]) that B1, B2 generate B with length at most equal to the integral part of a. For example, let IC(A) be as defined before Proposition 10.6. We may clearly identify IC(A) with a subalgebra of the algebra M,,,) (A) c B( 2(H)) of bi-infinite matrices with entries in A, equipped with the operator norm. Taking B IC(A), we may consider the subalgebra B, c B formed of all the diagonal matrices with entries in A and we let B2 k(C)It is then easy to check that f(A) < d implies that B1, B2 generate B with length < 2d + 1. Conversely, if B1, B2 generate B with length < m, then (A) < [ '+]. 2 a >
0
are
Then it follows
==
=
Remark. The
slight discrepancy appearing here comes from the fact that in products appearing in the subset Cd we do not specify that the first term of the product must lie in B2 or B, while in the corresponding definition of f(A) the analogous term must be in B2. This difficulty can be circumvented: one should then consider homomorphisms u: alg(BI, B2) 1 0 such that 11 U1 B2 11 and study the inequality Ilull :5 KIIUIB1 11"- See [PIO] for more variations on this the
---+
=
theme. The
case
kind, for
study of f(A) suggests examining
instance the
pair B,
=
IC(Al), B2
many other
=
)C(A2)
examples of the same A, c A, A2 c A
where
subalgebras. In particular, we may consider the case where A is product of two unital C*-algebras C1, C2: namely we take 1 (9 C2. All these cases are studied A C, (9 1 and A2 C1 Omax C2 with A, in [P10], to which we refer the reader for several illustrative examples and more information. See also [NW] for a discussion of the length of crossed products. are
two closed
the maximal tensor =
=
=
Notes and Remarks
on
Chapter
10
chapter (as in the preceding one) most references are given in the text. Theorem 10.3 is surely well known to specialists. Theorem 10.5 is perhaps new. The results on the length all come from the series of papers [P9, P10, P11, P12] to which we refer the reader. More recent results along this line appear in [P13, P14]. See also Le Merdy's papers [LeM5, LeM6]. In particular, [LeM6] develops a notion of length, specially adapted for the "dual case"' (i.e. for dual operator algebras, normal homomorphisms, and so on). For all the possible variants of length, the main open problems are the construction of examples of arbitrarily large length. We have been able to produce such examples among (non-self-adjoint and non-commutative) operator algebras ([P11j), but the same question remains open for uniform algebras, or Q-algebras, or even for commutative operator algebras (perhaps this last class can be treated by the same general strategy, as in [P11]). Note that it is conceivable that, like the disc algebra (see 9), all proper uniform algebras have infinite length. In [P9], we show that they all have length > 3, and the disc algebra case implies that the ball algebra or the polydisc algebra all have infinite length, but a general argument is lacking. See [Kis2] for a partial result in this direction. In this