Form Factors in Completely Integrable Models of Quantum Field Theory

b-.0

Form Factors in 0 (3)-Nonlinear a-Model

113

where po(x) is the function

a a l a l 1 a _ a 1 (00 (a) = T7_ 2xil r( \2xil r 2 + 2ai sha ' 0 2 2af ), which has no singularities on real axis. Hence 2n

Hp(

a -/3)-f

P=1

=

n

j=1

a1 -L A0 ( Q•)2

6(Ce

11 Ph(a -Qj) E (a-Qk)2+b2 11 (Qk -Qj)(2a n

j=1

n

/^

j$k

k=1

-Qj -Qk)

Thus

_

n

1

°°

n

1

da ri
1 x H )`4i(aIQ=1,... Q:nIQjI,... ,Q^,.) j#k (Qk - Qj)(2a - flk -,8j

(131)

The poles at the points a = z (Qk + Qj) are made artificially; as usual in such cases it makes no difference how to understand them. We can suppose, for example , that all Pk are slightly moved to the upper half-plane . Integrals in (131 ) behave as 6'1 for b -> 0. Using the formula lim b = irb(a) 6-o a2 + b2

one obtains nn

%ij pb -1 E

k=lp^k

sll (Qk - Qp)(Qk - )3p )

exp(n - 2j - 1)13k

x Ai(Qkl/il,... ,Q,LIQ;3,... ,Qjn) . Hence

det II j II = 6-n+ 1 det 11(2t'1'2((2))ij 11, (132) where 21 ( 2) is a n x (n - 1) matrix with the following matrix elements:

1= A i( Q;IQ;1,... ,I3 J13,,... ,Q;.) .

114

Form Factors in Completely Integrable Models of Quantum Field Theory

2Q) is a (n - 1) x n matrix with the following matrix elements: 20) = exp((n -2j - 1)9j)fl poi

1 -i3 )sh(Qi - Qp)

Recall that the set {/311, /2, ... , /3in } coincides with the set {,(31 - T" 61 + 2 , ... , Qn + 2 }. Due to a well-known theorem a determinant of the kind (132) can be expanded into the sum n

det 112((l)%(2) 11 = det II2(kl)II det II2((2)II k=1

where 2(k1) is a minor of 20) with the k-th column omitted and 2((k2) is a minor of 2((2) with the k-th row omitted. The determinant of 2(k1) can be evaluated explicitly:

det IIQt(1)II-(2) = 1 (1 IIsh(/3: /3)exP ,) 11 ( /3i-fli) > fls i<j i
(let 1 II2(k2 )IIee

= ;n (ai - ai )

k 1

jok

Notice now that if we consider the form factor f3 = i (fo - f1) the transformation On , -1 would change to On j and for On 1 (On) we would undoubtedly obtain Onj(An)

8 -n+1

/3:t

- 7ri

))

n sll(Qi i<j

exp

n

x II (Q1- ^3j) II (/ - Qj) i<j k=1 i<j

det II21k2)Ile-Pk

i,j$k

According to Theorem 3 of Sec. 6 exp (_Eii) eIj) ¢n,1(,&n) _ = exp ( 2

r , fl; ) (^e-flj') On,-1(1&n) ,.

(/3)

Form Factors in 0(3)- Nonlinear or-Model

115

hence for 6 0

I

n /q Wi - 16i)

k-1

e-13i)

detII`^lk2)Ileflk

i,i #k

E

(Qi1 _ ^^)

k=1 "<j.

det II21k2)IIe-fl. (^ ePi ) . ( 133 )

Notice now that det 1121(2) 11 are polynomials , and the exponent exp(,Q,) are linearly independent over the field of rational functions. Hence the following statement is valid. Lemma 1 . Consider a set ,Q1, ... ,,On . Let {Q! ,Q! } U {,Q! Q3. } be an arbitrary partition of the set {a1 - 2, 01 + #2 - 2,,132 + 2, ... , Nn + 2}. Consider now (n - 1 ) x (n - 1) matrices II ( k2)IIi.i with the following matrix elements:

II` k2)Ilii = Ai(QiIYj,... a,nla,,,... ,,8;,,) , j 0 k where Ai are given by (118). The following identity holds for every k, 1: / 1 det II2(2)II 1 = X det II2k2)II i #k (Qi -,(3i) - ,3j)

i^#r(,(3i

i
k
The proof of Lemma 1 follows immediately from (133). It is also possible to give an algebraic proof but it is very bulky. Let us denote the set,131 i ... ,6n by B and the sets ,Q! Q! ;,l3! ,l3'• by B', B2,B'UB'=B'=(B-2)U(B+ 2),(B+a {Qi +a}).Fixa partition of B' into Bi and B2; it induces the partition of B into four subsets B = B+UB-UB°UB according to the rule,0i E B+ if,Qi+ z „Qi - 2 E B2; Qi EB- ifQi+ 2,6i- ME BI ; )3j EB°if/3i+ jEB',Qi - a EB'; ,13i E B° if Qi + z` E B,/31 - a E Bi B. The function X introduced in Lemma 1 is a function of B-, B°, B+, B : X(B-IB°IB IB+). Evidently n(B+) = n(B-). The following statement holds. Lemma 2 . The function X(B-IB°IB IB+) vanishes if B° # 0. The function X (B- I BO IOI B+) contains the multiplier (except for the case B° _

116

Form Factors in Completely Integrable Models of Quantum Field Theory

0,n(B+) = n (B-) = 1):

II

II (Ni - /3j)2(ai -

aj

11 (Ni - aj - iri)

#(EB+ P, EB°

#iEB + #jEB x

II

- iri)2

II II

(Ni -,8j

+ ri)

.

l3;EB- #,,EB°

Proof. According to (118)

Ai ( a I B 1 I B2)

= 1a-N/- 2

P'EBi \

+

II Q'EB,

(

J

Ti a_13 ' +T )

WGi( a-7riIB2-7ri)

Q i( a IB)

.

(134)

According to Lemma 1, one of n realizations can be chosen for X(B-IB°IB IB+) : 1

X(B-IB°IB IB+) = detlI2t 2>II i

II

(13

-Qj )

i,j#k

Suppose B # 0, i.e .

B contains at least one element 6j.

Take for

X (B- I B- I WO I B+) a realization with k j then 2(k21 contains the column A(aj I Bi I B2). As it follows from (134) this column vanishes. Now let ai E B-,8j E B+. Consider the realization of X with k # i, j. For the column corresponding to ,8i one has

A t( Qi I B' IB2)

=

ll(li - a -)($i - a-

xQl +

( /3i

- 7ri)(f3i - a° - ri)

+ - ri + - 3ri ° 3ri

-riIB 2,B 2 ,B - 2

jj( ,ai - Q+)(ai - a+ + ri)(ai - /3° + ri) ,

( ( ri ri ° /^ T2) i xQl1NiIB-+ 2,B-- 2,B + -

where II(ai - a-) II \(ai - ak), etc. Clearly, the first term disappears PrEB-

(there is ,8i among a-), and hence II(ai -a +)(ai- a ++ri)(ai - a °+ri) can

Form Factors in 0(8)-Nonlinear a-Model

117

be extracted from Al(/3iIBiIBZ). Similarly ll(,3j -/3-)(#j -/3- -7ri)(/3j ,Q° - 7ri ) can be extracted from the columns corresponding to /3g. Thus X contains as a multiplier (/3i -Qj)2 ( #i -/3, -7ri ) 2. The cases /3i E B /3j E B° and /3i E B+, /31 E B° can be treated in a similar ways. Q.E.D. Lemma 2 implies the possibility of introducing the polynomial ( except for the case n(B°) = 0, n ( B+) = n(B-) = 1)

O(B

I B° I B+) = X (B I B ° IOIB +) (/3+ -

/3 - - 7ri ) 2(/3+ - /3-)2(/3+ - /30 - 7ri )(/-

-

/30

- Sri) .

For n ( B+) = n(B-) = 1, n(B°) = 0, the function 0 is equal to

For the constructive definition of q see Definition 2 to be given later. Let us return to formulae (130). We have to understand what the operation ( ) n turns into after the partition of B' into B - T", B + z and the projection onto spaces symmetric with respect to pairs of particles. The operator B(v) defined by A(a)

D(o-)/ Solo-Qi)... Sozn(O-'zn)

(135)

is of fundamental importance for the definition of the operation ( )n. We have to calculate B(aI/31 - a , Nl + 2i , • • • Nn - 2 , fln + 2 x P1,2 ... P2n-1, 2n, where P2i-1,2i is the operator P acting from Hi ^_ C3 to h2i_1® h2i ^, (C2 ® V. Multiply ( 135) from the left by IIP2i-1,2i and use the usual trick : present P2i - 1,2i as Pzi , zi-1P2i,zi-1 and move all P2i _ 1,2i to the left using the equation (see (128))

So,zi-1

C

7ri1

= P2i,2i-1So,zi

(

So,zi

Q - Qi +

(

0, -

Qi

7ri ^ Q - Qi - 2 Pzi-l,zi

- 2

(

)

P zi,zi - 1 P2i , 2i- 1So,2i ^ - /^ i

S0,2i-1

(

17 - /8i

+ 2

7ri1 ( -

2

7ri

0, Ni + 2 J So,zi -1 -

118 Form Factors in Completely Integrable Models of Quantum Field Theory

Hence 50,1(-fi1+

)&

2f

(c -'8 1-

J

...

7ri S0,2n-1 1 -Nn+2/50,2,, (^-Nn-2) rs a 7ri x JJ P2i-1,2i = fJ P2i-1,2iS0,1 - Nl - 2 ...

So,n

C

7ri l - 2

O - Nn

where So,i is an operator acting in ho ® Hi ^-- C2 ® C3 in the following way: asp,i( tT) = 1 (o - 7ri + Trio°Si) , tr-27ri

where tr° are the Pauli matrices acting in ho, Si are the spin-1 generators of SU(2) acting in Hi:

53 ...

1

10 0 00 0 00-1

Sl-

v

010 101 010

1 0 i0 S2^

7

-t Oi 0-i0

Define the operators

C(o)

D(o) /

'(a,) =

S 0,1(Q - ,Q1)

... SO,n(0,

The operators satisfy the same commutation relations as A(o'), B(cr), C(tr), D(tr), which follows from Sa,b(Q1 - D2)Sa,i(Q1)Sb,i(Q2) = Sb,i(O2)Sa,i(Q1)Sa,b(Q1 - 172)

The following relation holds: Si,1(Qi-fij)asa,1( 0-/ii)asa , i(Q-Ni ) = ass,ilk-Ni ) asa,1 (^-N1)Si,7lNi-Qj) ,

(136) where S is the NLS S-matrix ( 126). It can be concluded from (136) that B(ojf1, ... 'A , N41, • • • ,,8.)Si,i+l(Ni - A+ 1) = Si,i+l (fii - Qi+l)B(i7I )3l, ... , )3i+1, N{, ... , Qn)

Form Factors in 0(3)-Nonlinear a-Model

119

As before, we suppose Hi and Hi+1 to change places if /3i and Oi+l change places. Consider some function F(B' IBZ) which is invariant under independent permutations of the rapidities comprising Bi and B. The operation ()n was defined as follows: (F)n(j1, ...

, Q2n)

=

F(B1 IB2)

1

II

B'=BiuB^ 01EB i Pii fl9i T fl EBz

(137)

x (01 lI B(a;) . A^ EB2'

Partition rapidities into pairs ,0'' = 13 + j, Q2j-1 = f3 - zi . This partition induces, as was explained above, the ppartition of B into B-, B°, WO, B+, so we can define a function F(B_ IB°IB IB+) through F(B' IB'2). After B' is partitioned into pairs and projected onto symmetric subspaces , Eq. (137) transforms to

F(B IBOI- IB+) B=B-uBouB uB+

1

X

7ri )(a+ -

X (Q+ X X

- /3° -

7r i)(Q/^ +

+7r i)(a+

f/

- 3

-

/3-)2

1

°)(/l +

- N

°)(a+

- N ° + 7ri)

1 (/3-

-

/3°

- 7ri )(/ - -

,8 0 ) 1

11

(N- - i3°)(h3- - /.' ° - 7ri)( h'° - h'° - 7ri) 1

X (Q ° - Q ° - 7ri) (/3° - R 0)2

x (roll II B (a °)B(a+) B(/3 + + 7ri )B(Q ° + 7ri) , where ((Oil = 110 ei_i, and ei,i„(w = 0,±1) generate the base in Hi. The fact may give rise to misunderstanding that no singularities appear. As a matter of fact, the operation ( ))n for ITM does have singularities at the points /32J = /32j-1 + in. What has become of them? This contradiction

Form Factors in Completely Integrable Models of Quantum Field Theory

120

has a simple resolution: the residues of ( )„ at its poles belong to skewsymmetric subspaces, but we have projected it onto the tensor product of symmetric subspaces. Now we have to substitute the polynomial O(B- I B° I B+) for F:

On-1((An)) n6->b-n+1

O(B IB°IB+) B=B-uB°uB+

x

{E(,8+ -,3 - ) - ai(n(B+) + n(B °))}

X 11 (f3+-,Q-// -iri)) R0 - /^ (^+ 7r i 7r -,3- +

i)(, + - /3 0)(/- - 30)(N0 -

)(/3+ -

/3 -)

x ((011 11 B(a°)B (a+)B(Q+ + Ii) ¢^ ( x `>2 e

1

11 ( /3 q sh(/ - i3 )(F'i - Pj ) ) exp `- /7) i<j

the terms with B" # 0 disappearing in agreement with Lemma 2. Now that we have some idea about the degeneration of ITM form factors to the NLS ones , let us pass on to formal definitions. First , let us define a base in H1 0 ... 0 H;, consisting of covectors wwi,...,w,. (31

)

... A) =

((OII

11 j:wi=0

B(i3)

11

B(/31)B((3j

+

in)

j:wj = 1

wj = 0, ±1. This base is an eigenbasis for the operator .A(r) with the eigenvalues

11 j:w^=-1

o, -,6j o -)3j - 27ri

(138)

x ? ^3j - 27ri wwl,... ,w„ (Nl, ... , n j:w^=0

The base ww1.... wn is connected with the natural base of tensor product ew1.... Mn via a triangular transformation which means that in the expansion Cwl,...,w„t^l,...

wwl,...,w,.(Nl,... ,/3 Nn) = Ew,=Ewi

Nn ) ew ,1,•

w rn

Form Factors in O(3)-Nonlinear ,-Model

121

only those C, 1.... ,wn differ from zero for which (w1, ... , w,) < (W1.... wn), the multiindices being ordered as ternary numbers (for example, (0,-l) < (0,0) < (0,1) < (1 - 1) < (10) < (11)). The covector WW1 1... w,. (o1, ... , , n) can possess simple poles at the points ,C3j = f3 i + 2ii, /3j = f3i + ai; the poles at the points f3j = /3i+ai exist only for j > i, wj = 1, wi = -1. All above statements can be proven similarly to the Lemmas of Sec. 3. A base dual to w,,,l,,,//^^,wn (,Q1i ... (3n) can be defined: wwl,...,wn (N1,... ,fln)

_

((0il

11

B'( ,8j

+ 2aa) 11 B((3

+ 7ri)B' (Qj + 2ai) ,

j:w1=O j:w1-1

where B'(i3p + tai) =

lim B(o + 21ri )(o - ,6p). The following equation a^pp

similar to (80) holds (ww1....,wn P1,... ,Nn),,13m)) = bwl,wi ...bw„„w;,,

Definition

1. Consider a set of functions F (1 . ) 1 , . . . al+cIp 1, • • • ) /fin-21+clv1, ... , v,), c = 0,±1,1 = min(0, -c),... , [!5 ]. Operation (( ))n associates with these functions the following vector from Hi ® ... ® Hn:

Fn(B +)(B I B °IB+)

(({F}))n= E B=B- uBouB+ X 11

(#+

-,3- - ai)

(,o+ -,a- - ai)()3+ - P°)(,8 - - a°)(,Q+ - 3-)()31 - a ° - a i)

X wwl,...,wn(B) , (139) where wj = -1,0, 1 for fij E B-, B°, B+ respectively.

Definition 2. Polynomials 4e(B-IB°IB+) (n(B+) - n(B-) = c) are defined as follows:

0c(B jB°IB+)= II 11(Q+-P-)fk(B-jB°IB+)detMk i<j i,jq k fk(B IB°IB+)

1,,8kEB°,

/^

(1I(/3k -,3-)(#k - /3 - ai)(13k - j30 - ai))-1 , Pk E B+ (II(/3k - N+)(/3k - )3+ + ai)(/3k - N° + ai))-1 A E B-

122

Form Factors in Completely Integrable Models of Quantum Field Theory

where Mk is a ( n -1) x (n -1 ) matrix obtained by omitting the k-th column from the n x (n - 1 ) matrix M` with the following matrix elements:

M, =Qi +c

r

Ti _

MMIB

7ri

7fi

+ 2'B 2,B° 2

( B° - 321 - Sc,1o; I B+ - 2 ,B+ - 321 ,

(140)

for i = 1,... ,n-1„Q3 EB-;

M; = II(a, - a -)(/3 -,8- - 7ri)(,a; - - 7ri) Q°

X {

i_c

- bc, -1Q; x (/33 -

flj - iIB(

(B

#+

- -

B- B° 2

2

2

+ 2 B° + 21 + jj(^i - a+)

1B

+7ri)( Qi - (3° + 7ri ) { Q i+c (Qi IB- +

_ 7ri 7ri

B - 2B °-

-

bc1 Q;

l

2

,

7ri 37ri 37ri 1

B+ 2,+-

2

B°

2J

for i=1 ,..., n-1„Qj EB°;

M1 =

,

° (iii - iniIB - 2 , B+-321 B 21) iri bc, -1Oi (B - - 21,B + 21)

,

for1
0 0 (a-I 0 I)3+)

7r1

- ,Q--7ri

Let us discuss an important point . ITM form factors depend on even numbers of rapidities . NLS form factors obtained from the ITM ones depend on arbitrary numbers of rapidities since an NLS particle is created

123

Form Factors in 0(3)-Nonlinear or-Model

by two ITM kinks. In the space of states of NLS one can introduce the operator of charge conjugation, postulating its properties as follows:

CIph) = I ph) , g

CZw (Q)C - 1

= - Z,,

( )3)

Section 2 implies that even and odd parts of an operator are mutually independent which means that both parts are local operators . That is why the form factors of one local operator in ITM create the form factors of two operators in NLS , one of which is provided with even particle form factors, while the other with odd ones. Hence the form factors fµ, fµ., create four sets of form factors in NLS: i

a liM b-n+1 a i

fµ(^31i... ,h'n) = h_n

f(P1l...n) I

2 " ` +i6 P ei-1=Q;- z

x P1,2 ... P2n-1,2n IJ th2(a, - ,Qj) , n =- O(mod 2) i<j

f a (^1^ ...

p Nn)

= liM 6-n+l a /^, l (NI

f

6^0

.. .r

X P1,2 ... P2n-1,2n (^ sh,Oj) /^ qq fµv(F31,... ,

,(3n)

i

i JI

l n th22(ai

'+i6

- i3) ,

n = 1(mod 2) ,

<j

l

i iM -n+1 fµ= 6^0 6 ... p1"

"'201

T' +ib

X P1,2 ... P2n-1,2n ll th2 2(,Qi q q f(al, ...

- /3j )

,

n O(mod 2) ,

i<j

+1f

00 p1, • • • , 02n)) .Nn ) = liM 6-n ^c_n P2; =P;+ ^ - : 6

'i +ib

.,, 2 1 E(ch)Qj )2 - (Esh pj )2 - 1 XP1,2 ... P2n-1,2n 11th 2 (Ni - aj (Esh /3j)2 i<J

n - 1(mod 2) . We hope that the use of the same notations for the NLS form factors in the RHS's and for the ITM form factors in the LHS's will not cause any misunderstanding. Additional multipliers Hth2(,(3i - ,3j) and (Ech,Qj )2 (Esh /3j )2 -1 are introduced in order that form factors possess proper structure of poles; obviously they do not influence the validity of Eqs. (141), (142).

124

Form Factors in Completely Integrable Models of Quantum Field Theory

The constructive definitions of f;,, fa, fµv, f are

(Ni-Qj +7ri J3(t1,...,n)=2- Mllth22(Qi-13j) i<j ^i-Qj )

x

E(e,6j - (- 1)µe- 3i )(({ ^° }))n

, n

O( mod 2) ,

^°(B- I B°I B+) _ O°(B- I B°I B+) (E(a+ -,3-) - ini( n(B +) + n(B °))) f/t(,8 ,...

fn) = 2-

th21 (Qi

VMII i

x {((¢1))n + (_1 )

-,13j)

<1

+7fi

Ni

13

aj

a ((10-'}))n} , n = 0(mod 2 ), a = 1, 2,

f3(F^1,...^n)=2-*'II th2(Qi-^1) ^'^t^ (({^°}))n i<j

)

n=1(mod2),

fa(N1 ,...

On)

= 2

^

i

a

^s-

th22(Pi-

\ `


j+^i

13i - 13j J

x {(({01}))n + (- 1)a(({0-1} )) n} , n = 1(mod 2 ) ,

fµv(31,. . .

x

pp F' n) =

(E(efii

2-

^

ai - flj +ai

M 2 ^ 21 th 2(Nqqi

fli - Qj

i
-

a = 1, 2 ,

(r(eQi - (We L^

J

(( -Qi)) {0

l

° }))n

n =O(mod 2) ,

f (fl,. ... ,.3n) = 2-g'-M2 th2 2(1i -,3j) CQi R' Nj fl' ^tl (({0°}))n i<j 11

x I(Ech,Qj)2-(Eshfj)

2

-1

]

,

n= 1(mod2),n>3.

The reasonings presented at the beginning of the present section implies the validity of the following statement.

Form Factors in 0(3)-Nonlinear o-Model

125

Theorem 1. Form factors fa , f a, f,," f satisfy the requirements /^ //^^ //^^ w„ ww;+1(f /^i /^i+1) -)3 f (Qi, ... , Ni,+1.,. Ni+)wi . .. w.,w.+i ,... ,w,.Swi t}1 , f qq1i,. f(^1,...,F'

,.q Ni,•n.. fln) wl,...,w'+,,w', ...,w,.,

(141)

f(fi,... , fin-1, Qn + 27ri) wl,••• ,w+.-l,wn

(142)

= f(i3 , i1, ... , fn-1)w,.,w,,... ,w,._1

The connection with ITM form factors implies that fµ, fa generate triplets and fm,,, f generate singlets with respect to the action of SU(2) whose generators are Ea = ES;. This fact clarifies the equality of the minimal number of arguments of f (Q1...... On) to 3: one-particle space has no singlet subspace. Now we proceed to the most difficult problem which is the calculation of residues of form factors. Unfortunately, in contrast with Eqs. (141), (142) it seems to be impossible to obtain formulae for residues in connection with ITM. First, let us elucidate what singularities form factors as functions of fin have in the strip 0 < Im fn < 21r. The only singularities are simple poles at the points ,Qn = ,ij + in. Let us explain this fact. The operation (( ))n is regular in the strip besides simple poles at the points ,On = ,Qj +27ri. The covector fln) has also simple poles at the points fin = /3j +7ri for wn = 1, wj = -1, but they are cancelled by the multiplier II(,3+,Q--7ri). The multiplier Hi<jth2 2(fi-,Q3)(fi-,13j+7ri)(fi-Qj)-1 cancels the poles at the points Nn = ,13j +21ri and produces simple poles at the points fn = ,3j + in. As usual, the multipliers (E(exp(fj) - (-1)0 exp(-,3j)) in fµ and (E(exp(,3j) - (-1)µ exp(-fj))) x (E(exp(,ij) - (-1)" exp(-,Qj))) in f,," cancel the poles in minimal (two-particles) form factors; (Ech pj )2 (EshPi)2-1 in f serves the same purpose for the three-particle form factors since 3

(

2

ch/3i ' j=1

3

2

3

- Esh,ij -1=2+2Ech(Pi j=1

i<j

3 =8flch2(fi-fi) i<j

For the calculation of residues of the form factors we need the following statement.

Form Factors in Completely Integrable Models of Quantum Field Theory

126

Lemma 3 . The following equations hold:

O(B U Q I B°IB+U/3)=O(B IB°U QI B+), U fIB°I B+ U (a +i i)) _ iri o (B-IB°I +) c(B x

[ll( ^3

-

/°

+iri)(N-

- ll(,3 -(3° -

(143)

/^ B /^ ar °)(N-N +7ri)(F3-/3+)

-/3°+27ri)(/3 -,3- - 7ri)(,3- /3 ++27ri)]

7r i)(/

B+UB-UBO #0. (144) To avoid piling up of indices we have denoted ¢° by 0. Proof. Consider, at first, Eq. (143). Recall that

1 4( B- U a1 B °i B + u a) = III i< (fl - fl)

H

P+EB+„p

i,i#k A-EB-up

x det Mk(B- UQIB°IB+ U,9 )

fl

1

B

U PIB °IB+ UP)

,

igEk

(145) where Mk is an (n - 1 ) x (n - 1) matrix, n = n(B+) + n (B-) + n(B°) = 2n(B+) + n(B°), with matrix elements given by (140), /3k E B- U B° U B+. The two columns which correspond to ,3 E B- UP and ,3 E B+ U ,3 are placed last . Use Eqs. (112) which imply + - 7ri + - 3ri ° 3ri 7ri 3ri Qi ( iB 2 ,B 2 B - 2 ,#2 ,P2 Q

B+ - 3ri B° - 37ri - 3ri (aiB+ - 7ri ' 2'

2'

2'

2

7ri + - 7ri + - 3ri o 37ri 3ri ,3- 2 Q:-i (ajB 2 B 2 B - 2 ,Q- 2

Qi aIB

_

ai

- 2 B

=Q ( a

B-

_

iri ° Sri

ai ai l

+ 2 ,B + 2 ,N - 2 ,Q+ 2 /

7f°

- 2,B

7ri

+

7ri

B + 2,a+

Ti

( /3 - 7r Qi-1 ( lB

-

-

2

_ -

B +

7fi

2)

7ri ° 7ri Ti

+ 2 ,8 2 ,/9+ 2 /

(146)

Form Factors in 0(9)-Nonlinear o,-Model

127

Equation (146) allows us to rewrite (145) as follows:

O(B U l3I B° I B+ U Q) =

11 (,3+ -# -) Q II (/3i1- /3,i) (i +EB+ i#k lI ( - /3i)

i<j

P-EB-

x det A1k fk(B

IB° U)3 IB +)

where Mk is a (n + 1) x (n + 1) matrix whose left-upper corner coincides with the matrix Mk (B- J B' U /3IB+). Two last columns are equal to + 7ri B - Ti

aIB ' 2'

Q'

B°

- 7ri

+ Ti

Q 2' 2' 2) B+ - 7ri B° - 37ri )3- 37ri Qi (/3- 7riIB+ - 37ri 2 2, 2 2) Elements of the last row and the first (n - 1) columns are equal to

Qn +1 Qn+l

/3i

-7r iIB

+ 2 2) ' QiEB ,

+ - 37ri + - 7ri ° - 37ri 37ri

2 'B

2'B

_ iri , _ 7ri ° ai i , 7r 3 + 8 + 'B +

2

2

2

2)

' /3iEB

- /3- - 7ri )(,Qi - /3° - 7ri )(Ni - /3 - 7ri)

79 x Qn+1 (/3i - 7ril B+ - 32 ZZ' B+ - 2 ' B° - 32 ^'

+ H(ai -

/3+)(, i -,6+ + 7ri)(Yi - 3 77°

0

2t

+ 7ri)(/3i - + 7ri)

7

7°

q xQ+ (/3dB - 2,B - 2,B + 2,,6+ 2) ,

/3iEB .

(147) Notice that the number of arguments in Qn+1 in (147) is equal to n + 1; hence one can use Eq . (129):

Qn(B)(aIB) = II (a_13_

)_ II (-,(3+ 2)

(148)

PEB PEB

Substituting (148) into (147) one proves that all the functions in (147) are equal to zero . For the last two elements of the last row one has 7riIl(/3-,3+)(P -P++iri )(a-N°+7ri) , -7rill(N-F' )(N-l3--7ri)(Q-/3°-iri) .

128

Form F&ctort in Completely Integr&ble Model* of Quantum Field Theory

Now expanding the determinant along the last row one obtains a sum of two n x n determinants with identical first n — 1 columns. This sum can be rewritten as an n x n determinant with the same first n — 1 columns and the last column being

+(-*«) n ^ - /no? - v - 'O^ - /?° - »o Evidently we have obtained det Mk(B~ \B° U P\B+). Let us pass on to the proof of Eqs. (144). Applying (121) twice, one obtains Qi(at\B,p-j,p+jy)=Qi{a\B)-2PQi_1{a\B) + (/J-y)(/J+y)Q«-i(«|B). Further using the identities

QnW(a\B)=n ( « - * - ? ) - n ( « - * + T ) <J.
»n(-*+7) we transform det M t ( B _ U /?|B°|S+ U (/? + Tt')) to the following form: its left upper (n - 1) x (n — 1) corner coincides with Mk(B~\B°\B+), its two last rows of the first n — 1 columns are equal to zero, its right-lower corner is a 2 x 2 matrix n(/S - p~)(p -P~ - wi)(0 -p" - xi) -n(/9 - p~ + *i)(/3 -p-)(p-p°)

n(/S - 0+ + iri)(/9 - /3+ + 2«ri)(0 - 0° + 2iri) _n(/9 - /S+X/5 - (5+ + »iX/9 - 4° + wi)

hS-

^ . J n ( / 5 - / 3 - ) ( / 3 - / 3 - -iri)

( /3 + y J 11(0 - 0+ + 2*t)(0 _ /3° + 2iri)

X(/J -

/»" - iri) - (p + y j n(*j - p°)

x(p - p+ + «•) - f/j - y ) n(/j - /s+)

x(P-P~)(P-p-

+ iri)

x(/S - 0+ + irO(/J - /S° + »i)

Form Factors in 0(3)-Nonlinear o-Model

129

The determinant of the last matrix is equal to

ll(a-a-)(8-,Q++in){11(#-a°+ini)(,8-a°)(,a-a-+in ) (,a - a +) - ll(a - ao - iri)(a - a° + 2ai)(Q - /3- - 7ri)(/3 - a+ + 2ai)}

ri

Q.E.D. Remark . It should be noted that the recurrent relation ( 144) has appeared in another branch of the theory of completely integrable models, which is Korepin 's approach to Green 's functions (see, for example review [24]). We hope that the explicit solution of these relations as provided by function 0 will lead to progress in the framework of this method. We approach the calculation of residues of the form factors at the points Qn = /3j + in . The only proof we know of is rather cumbersome, so the reader who is interested in the result rather than the techniques may omit it. Theorem 2 . Form factors fµ, fa, fµ,,, f considered as functions of ,Qn have in the strip 0 < Im/3n < 21r only simple poles at the points ,Qn = /3j + in, j < n - 1, the corresponding residues being

2 7ri res f X

X

N1

...

h' n wl, .. ,wn = (-1 )

f(/ i,... ,/3j,... bwi

qq iNn-

bw .,, -wi

q

b" i-1

Swn-i,wj { w1 wn-1 wn-1, r1 (Nn-1 S,w q -.. Sr'7 wi r1 ,w (^9 S11 h^l) wi,wj -1

S

+l, rn - j -s

wj+l,wj

(F'j+1 - flj)

wj+1 wn-1 (Nj - Nj-1)bwj+1 . . bwn-1 }

Nn=/3j+ 7ri.

(149)

In this formula f can be replaced by fµ, fa, fµ,,. Proof. Consider any form factor, for example, f3(31, ... , /3n). Evidently it is enough to prove (149) for j = 1; other j can be considered using the symmetry (141). Let us introduce the notation a 4 1 F(/31,... ,/3n) = () Hcth(fli_/3i)f3(/3i,... ,/3) . (150) i<j The function F is regular at the point Nn 3= /31+iri. Eq. (150) in conformity to F is equivalent to

F(,81,... ^Qn) ^Pn=P1+ai = F(/2,.... ,,3n-, )singn,l qq

X {U(Nl 132, /33, ... r fln-1) - 1}

Form Factors in Completely Integrable Models of Quantum Field Theory

130

where singn , l = en,-1 ® ee1,1 + en ,l ® el,_1/- en,o ® el,o RR /q //^^ U(/11, 2, ... , fan-1) = Sn-1,1(/n-1 - 01) ... S2,1(N2 - N1)

Later on we shall denote U(/31I,Q2i ... , /3n-1) by U(/31) if the context does not lead to misunderstanding. We shall extract explicitly the matrix structure of U(/31) with respect to H1, writing as Uwi (13l). The proof is divided into two parts. Part I. It is sufficient to prove the identity

F(/31i ...

,i3n) wi,w ,.IPn =^1}xi = (- 1)wnbw^i - w

;F(32 .... ,i3n-1) (151)

61) - bwi } X {Uyw, (i3

for (wl, wn) = (0, 1), (-1, 0), (-1, 1). Proof of Part I. First, the formula

F (81,...

,6n )wl,...

,w,

=

F (81,

(152)

...

implies that if we prove Eq. (151 ) for (wl, wn) = (0,1), (-1, 0), it will also be proven automatically for (w1i wn) = (0, -1 ), ( 1, 0). So only three components remain : ( w1) wn ) = (-1, -1), (1, 1), ( 0, 0). Using once more Eq. (152) one makes sure that it is sufficient to consider (w1, wn) = (1, 1), (0, 0). Thus our purpose is to prove Eq. (151 ) for (w1i wn) = (1, 1), (0, 0) assuming its validity for

(w1, wn ) = (0, 1), (-1, 0), (-1,1), (0, -1), (1, 0), (1, -1) . Consider the case (w1i wn) = (1, 1). Rewrite the identity in question extracting explicitly the indices which correspond to the particle ,Q2:

F(/31, #2. ...

, Nn)1,w2i...

,1I/3*= P1+,r i

= F (#2. ... ) w^

W/ w' (#

X Uwi

(/31)S1,w2 2

2

- Nl) ,

where U(Q1) = U(j31I(33i... „Qn-1), the second term in brackets has disappeared since 61 1 = 0. Three possibilities exist : w2 = 0, -1 , 1. Let us consider these possibilities in turn.

131

Form Factors in 0(3)-Nonlinear o-Model = 0. The identity in question is rewritten as follows: 1. Let w2 #2

F (#2 . ... )0S1,O (Q2 - N1) F(/31 , ,. . , /3n )1,o ,... x Ui 1(Q1)+F(132,...)1Si' (f32 -/31)Uo 1(#l) Using (141), (142) write a sequence of equalities:

F(/31,/32,...

, /3n), ,0,...,1

[SO1(f1 -

Q2)]- 1{F(N2,#1,.../^ Nn)1,0,...,1 /32)1 -1

=?p - S0,1 (61 - 132)F(j31, N2, ... ) Nn)0,1,... ,1} = [S0,1(h'1 -

x {F(13,, • • • ,,Qn, Q2

^21ri )o,... ,,1,1 +/

,^ - So'l(f31 -, 2)F(Q1,Q2,...

_ [So' ( , -

132)]

Nn)0,1,...,1}

{F(/3,,... , 02 + 2ri, Nn)o,... ,1,1Si'

( N2

-

'n

+ 27ri )

13 - Soo: (#1 - 62)F(Pi,N2) ... , #n)0,1,..., 1} .

We suppose the value of F(#,,.. . /n)o,...,1 at the point is known and is given by Eq. (151). Hence L So; 1

F(/31, N2,

P1- /32)1 -1

x {51;1(132 - /31 +7ri)F(... 12 +27ri)w,S,yi 1 2(fl2 - /31 + 27ri)Ul i(N1) q

w^

-50,1 ( fl, - #2)F( ,82,.

F(#2, ,63,. .. x

w'2

N2 - /31 )} w^Uw1 50,1 (/^

,/3n_1)w2,[S0,1( /3, - $2)

s- 1;1 ( /32 - 3, + 2

7ri)Ul

1- 1 {S1,1 (32 - /31 +irt)

l(a1)bi 2 - S;^(al -

/ 2)

So;°(

32

- al)

x Ui 1()3l)bi' - S;i(f1 - l2)S' (f2 - Nl)Uo 1(/tl)bo'} Using the unitarity and crossing symmetry properties, one obtains the required result. 2. Let w2 = -1. Using Eqs. (141), (142 ) one obtains

O'O -1 x {-F(/31, /32, ... , /3n)o ,o,...,1 S-1,l(31 - /32) - S-11(/31 - /32) 1,1(/32 - /3n + 27ri) x F(/31, /32, ... , in)-1,1,... ,1 + S1,1

x F(/3,,... ,/32+27ri,/3n)-1,...,1,1} . (153) Using ( 153) and supposing that F(,31, ... , /3n)O,... ,, and F(,31,... /3n)_1,,.. ,1 for On = /31 + 7ri are known , one obtains Eq. (151).

132

Form Factors in Completely Integrable Models of Quantum Field Theory 3. Let w2 = 1. The following identity holds: / q //^^F031,#2, ... , Qn)1,1,... ,1 = Sl,l1,32 - 3j)Sj,l (N2 '61 + 27ri) x F(,Q1, N3, • • • , 92

+ 27ri, Qn )1,w3,... ,1,1 .

(154)

If w3 = 0, -1 we calculate (154) at the point ,3n = ,131 +7ri using the results of the previous subsections. If w3 = 1 we use (154) one more time, etc., until we get w = 0 or -1 for the first time (we shall reach w = 0 or -1 without fail because Ewe = 0). Let us outline the proof for (w1, wn) = (0, 0). We assume Eq. (151) to be proven for (w1, wn) = (0, 1), (1, 0), (-1, 0), (0, -1), (1, -1), (-1,1) and consequently, according to the proof given above, (wl, wn) = (1, 1), (-1, -1). We consider again the three possibilities w2 = 0, 1, -1 in turn. /1. Let w2 =//^^0. Using Eqs. (141), (142) lone obtains qq F(fl1, f32, ... ,N n)o,o,... ,o = [SO'/,1(N1 - R2)]-1{-5-1,1(131 - N2) R

x F(h31, Q2, ... to

1,-1/

,8n)-1,1,...,O - S-1,1 \/31 - j32)F(31, #2,... , fln)1,-1,... ,o

+ S1'0(/32 - )3n +

27r i)F(,l1,

... , #2 + 27ri, i3n)-1,... ,1,0

of

q + S110(/ 2 - Nn + 27ri)F(,31, ... ,,82 + 27ri, 8n)-1,... ,o,l} .

Substituting F(,Q1, ... , Nn)wl,.•. ,w,. for ,fan = /3 + 7ri, (wl, wn) (1, 0), (-1,1), one obtains Eq. (151) for w1 = w2 = wn = 0.

= (-1, 0),

2. Let W2 = 1. Using Eqs. (141), (142) one obtains //^^ F(#,,,62,.. . , /3n)o,1,... ,o = [S/;o (/31 - /32)] ' {-So1// (131 -N2) x F031,,32,. .. , Nn)1,o,... ,o + S00:00(#2 + Nn + 27ri)

x F(,Q1, ... ,132 +27ri,,fan)1,..., 0,0 + F(931, ...

02 + 27ri, ,(3n) 1,... ,-1,1 So,o' 1(32 - Qn + 27ri)

+ F(,81,... , #2 + 27ri, /3n)1,... ,1,- 1So,o 1(/32 -

,8n

+ 27ri)}

Substituting F(,Q1, ... „ l3n)wl ... ,wn for /3n /31 + 7ri, (w1, wn) _ (1, 0), (1,1), (1, -1), one obtains Eq. (151) for w2 = 1, w1 = wn = 03. The case w2 = -1 is quite similar to the case w2 = 1. The proof of Part I is finished. Part 2. Function F(i31i ...

_ (-1,1), (0,1), (-1, 0).

, Nn)u 1

_,,

v,n

satisfies Eq. (151) for (w1, wn)

133

Form Factors in 0(3)- Nonlinear a-Model

Proof of Part 2 . At first, notice the following circumstance. Since S(f3 -

Ql)

= cistlA - a; + 7ri)c l

t

singl ,nA1 = singl,ncnA „ Cn where cl is the crossing matrix c acting in H1, tl is the transposition with respect to H1, A is an arbitrary matrix, one can change in (151): U(,811,62, ... A -1) -+ C1 Vt1 (Q1 I/32, ... , Qn-1)Cl

where V(1311/32 ,../^. ,Nn) q

= Sn,2(i31 - 02 + 7ri ) ... Sn,n-1 (31 - /3n-l + 7ri) .

The matrix S(/31 - /3j + vi) can be presented as follows: /^ q

N£1

i (- /3j + ) •Swi:

(/31 - F'j +7rt) ( W

// _ .r El>w 2 X s 1

//^^ qq i wz (Nl - Ni + 7ri) W,2

flj + 27ri

w2 (,3l - #j + 27ri)Pwi'£1

Hence /^ n-1 _T7 w' (/31 -,w^ j) P 1£/TE /i(^1 +7ri) Vw 101) 1 1

11 ( fli_/3j+21rj) 1

j=2

r

£1 i£1

(155)

x TE/(l31 +27ri)P.1

Here and later on f(fl) = r(/3 /32, ... , /3n - 1). For example, A(/31 + 7ri)A(/31 + 27ri) ll (/1

a1 Qj ++27ri )

The following identity also holds [22]: (P

)£1 £1/Ta1 (ill + 7ri)7ai'(Nl + 27ri)(P-) o vl//

^ ^

al - Q;- + 27ri )l

a;

°18`1 °1 6£i

(156)

134

Form Factors in Completely Integrable Models of Quantum Field Theory

which implies for example

.A(/31 + ai) B(/31 + 27ri ) - B(/31 + 7ri).A(Q1 + 27ri) = 0 . Let us prove Eq. (151) for (w1, wn) = (-1,1). Eq. (151) can be written in the form

((oll E

jI B(/3°)B(3+) B(/3+ + 7ri)^(B

IB° IB+)

B=B-uBouB+

X

X

11

/(/3+ /- Q- + iri)

(,13+

- Q- + 7ri

)(/3+

,

- 3 0)(,8- -

00)( Q+

-

l3 - )(/3°

- fl° - 7ri) }

P_ 1,11pn =p 1 +*i

11 B(/30)B(#+)B(#+ + iri)O(B - I B° J B+)

_ ((°II (B\31,fln)= B-UB°UB+ 1

X 2 (Sn )2 X

(/3+

-

9-

-

ri)

(a+ -,Q- + 7ri)(/3+ - l3°)(l3- - /3°)(/3+ -13-)(13° - /30 - 7r) x (A(/31 + 7ri).A(/3i + 27ri )1 Gi /3 1 - +i ) - 1 I (157) -/39+27ri /) where P_1 , 1 is a projection operator onto el ,_ 1 ® en,1 0 Hz 0 . • • , ®Hn. What terms in LHS of Eq. (157) contain ((0II(Sn )z, i .e., are not annihilated by the operator P_11? The triangularity of the base w,,.,1 ,wn(/31 , ... , /3n) implies , at first , that these are the terms with ,Qn E B+. Present B(o) in the form

B(o) =

a1(o) A (o)bn(o)

+

al(o)B

(o)dn(o)

+ b1(o)C(o)bn(o) + bl(o)D(o)dn(o)

(158)

where

C

Cl(o)

dl(o) /

SO,1(o

- /31), \ C

n n(o)

dn (o)

SO,n(o - Nn)

the partition into the blocks being made with respect to ho. Note that

((Ollai(tr) = G -/3i-27ri o -,Qi ) ((°II, ((olldi (o) = ((oll

Form Factors in 0(S)-Nonlinear o-Model

((OIIbi(o) =

xi ) ((Ou1Sf , G - Qi - 2^i

135

((O fl ci( o ) = 0

Consider a term with Ql E B°, B+ in LHS of Eq. (154 ). Move it to the left and apply it to the vacuum vector

((OII B(al ) = 2 ((O ISj . (159) The expansion ( 158) shows that B(o) does not contain the raising operator Si and consequently further application of the operators cannot annihilate Si in (159). Hence those terms in LHS of Eq. (157) for which #1 E B° or B+ are annihilated by P-1,1. Thus only those terms in LHS of Eq. (157) are essential for which 61 E B-, On E B+. To calculate ( (An - Pl - x i)

°II (B\P1,Pa )= B-UB°uB+

An - Al + ai )( An - 01)

) B(An ) 13(An + ri)

X r j B (A°)B(P +)B(A+ + ,ri)4(B U P1 IB° I B+ U An ) (Al - P+)(Al - A+ + xi) (A1 - P- + 2wi)(Pl - A+ - * i)(A1 - P° + ai )(P1 - P°)(Ai - P- +,ri)(A1 -,6+)

(P+ -,6- -,ri) P11 X H (P+ - P- +Wi)(P+ - 000- - P°)(P+ - P-00 7P - *i) IPw=Pi+*t-

let us use the following trick: put before P-11 the product

S( Yn-1 -,3n) ... S( 02

- Nn) S(pn

- Q2) ... S(Qn -

Qn -1) = I

obtaining

W

II (B \P1,P2 )= 1

U B_

UROUB+

( (On - P l - * i) B(Pn ) B(An +,r i \(Pn - Pl + ,ri)(An - P l)1 )

X 11 g( P °)g (P +)g (A+ + ,ri)O(B - U PuIB°IB+ U (01 + *i)) X X

(P+- P --si) (P+ - P- +,ri)(A+ - A °)(A- - A°)( A+ - P-)(A° - A° PI - P-)(Pu - P+ +,r i) (P1

(

- P- + 2,ri)(Al - P+ - ,ri )(P1 - P° +,ri )(P1- P°)(Pl - P- + -i)(Pl - P+)

Sn,2 (Pn -

02 ) ... Sn,n -1 (An

- Pn-1)

(160)

Form Factors in Completely Integrable Models of Quantum Field Theory

136

where ,B(o) is constructed via 7"(o) = T(oI,Q1, Nn, R2, ... , Nn-1), i.e.,

B(o) = (a1(o)an(o) + b1(o)cn(o)B(0)

+ (a1(o)bn(t) + b1(u)dn(o))D(o) Direct calculation gives

((OIIB(Qn)B(/n + 7ri)(, n - 01 - 7ri ) Ip,. =A1 +xi _ (-ai)((01I((S1 ) 2 + (Sn )2

- S1 S.-),

(161) o -1a Q2

((0II((S1)2 + (Sn )2 - ST S.-)e(r) _ (o, (T1 X ((011((S1)2 + (S )2 - Sj S)a(o) .

()(o13

k - in 37ri) (162)

Substituting these equations in Eq. (160) and using Eq. (155) one obtains

II B(a0)B(a +)B()3+ + iri)m(B- I B°I B+)

(roll

(B\#1,f3,.)= B-uBouB+

x (,d+ - Q- - Ti) (l3+ -13- + 7ri)(a+ -,80)(,8- -,80)(,8+ - fl-)(l3° - /3° - 7ri) -N+ 27ri)1 X I-1 -rj (a1 - ^° + ^a)()/q'1 -^3)(/ l'1Z)a1 +-N+)1a1 ` p (N1 )(N1 00 ) x

A(# , + 7ri )A(N1

+ 21ri)

(Sn 2

2 I

(

(Pi'

+ini)

Recall now that the covectors ( (OlllL6()3°)a(f3 +),6(,a++7ri) are eigenvectors for A(o) with the eigenvalues

(roll II g(a°)e(a +)g(a + + (o =

-

,(3

7ni)

A( o)

)(o - P° 7ri )

(o - ,3- - 27ri )( o -,8 0 - 27ri)

((Oil

+ 7ri) .

(163) This observation finishes the proof of (157) for (wlwn) = (-11). Consider now w1 = - 1, wn = 0 . Eq. (157) reduces to

Form Factors in 0(3)- Nonlinear or-Model

137

((Oil L, 11 B(o°)8(0+)g(#+ + *i)^(B-IB°IB+) t B=B-uB°UB+ (#+ -

x

(P+

P-

-

xi)

- P- + xi)(P+ - P°)(P- - P °)(P+ - P-)(P° - a° - xi) } P-''°

Pw=P1 }xi

E 11 1j (P°)g(P+)AJ(P++xi ) ^(B-IB°IB+)

=-7((°11

(B\P1,Pw )= B-UB°uB+

x

1

f

+

xi)(P+

x sn A(P1 + xi)8(P1 +

- P°)(P- - P°)(P+ - P-)(P° - P° fl ( P1 - P

2xi )

fEB\91 , P,.

xi)

1

P1 - P+2xi

(164)

where P_1,o is the projection operator onto e1,_1 0 en,o ® Hz ... Hn-1. It can be shown that only those terms in LHS of Eq. (164) are not annihilated by P_1,o, for which Qn E B+,B°,N1 E B-. For Qn E B,61 E B- the LHS of Eq. (164) can be calculated similarly to LHS of Eq. (157):

F, fl B(#') B(#+) 13(#+ + xi )6(Pn)Ii(Pn + TO (rB\p1,Pn )= B-UB0UB+ l

^(P1,B - IB°IB+, P1+xi)

x\(Pn (P1+xi )(Pn) 01) x

11

(P+-P--xi)

(P+ - P- + xi)(P+ - P°)(P- - P°)(P+ - P-)(P° - P° -xi)

-)(

x

(Q1 - P P1 - P+ + xi) P -1,0 (P1 - P- + 2xi)(P1 - P+ - xi )( P1 - P° + xi )(P1 - 0 0)(P1 - P- + xi)(P1 - P+)

= ((Oil

E rJ g(P°)d(P +)g(P+ + xi ) ^(B-IB°IB+) (B \91,P2) = B-uBOUB+

x

H (P+ - P- +

(P+-P-x

xi)

i)(P+ - P- )(P- - P °)(P+ - P_)(007 00 - x i) Sn

n-1 PI - P1 1

x i=2 (P1 - P; + 2xi)) (A

(P1

+ 2xi)t33( P1 + 2xi) - A(P1 + xi)d(P1 + 2 xi)) .

Form Factors in Completely Integrable Models of Quantum Field Theory

138

Substitute this in Eq. (164). As a result, Eq. (164) is reduced to

((Oil

BOO

E

(B \Q1,pw)= B-UB°UB+

(- 7ri)(Qn - i3) II

x m(B , Qi I B °, #1 + iI B +) 11

+

(Q+

(Q+

)

1

- N -)(#° - Q° - 7ri) 11 (Yl - /3+ - 7ri)(N1 - 0°)(/1 -

1 x (i3 -

Q

+

7ri)(,Ql

-

+ in )

- a- (+ 7ri)(,O+ - Q°)(Q- - Q °)

1 x I

B(Q °)B( i3 )B(a+

0 °)( ,31 - a°

a+)

+ 2 7ri ) P_ 1'° I3„=p1 +xi

_ -((Oil jj B(l60)B(a +)B(,6+ + 7ri )O(B I B° I B+) (B\p1,p„ )= B-UB°UB+

x (a+ - /3- - 7ri)

+ 7ri )(/3+ - a°)(a+ - a-)(a° - a° - 7ri )(a- - a °)

- f0 + 7ri) )(a1 -,8 (Q1 - Q 1 + 2-01

Sn B(,Q1 + 27ri)

,

( 165)

where we have used the identity (156). Calculate

((Oil

H B()3°)B(f+)B(Q+ + 7r i) B(,13n)P- 1,o

for some partition of (B\,31 i Qn) into B-, B°, B+. Substitute B(a) in the form (158):

B(O) = a1(cr )A(a)bn (r) + a1(a)B(o,)dn(o,) + b1(a)C( o)bn(i) + b1(o,)15(o, ) dn(or) .

(166)

The last two terms can be omitted because they create ST. We state that

((Oil II B(a°)B(Q+)B(/+ + et) =

11 (a° -,61 2eni)( Q+ -

?1 -

x ((011 II B(Q°)B(a+)B(a+ - 7ri) + (terms containing Si) .

/3 - 7ri)

27ri )(a +±

(167)

Suppose we have proven (167) for some subsets of {,3°} = B1, {/3+} = Bi . Let us apply one more operator B(,(33 ), /33 E B°. The last two terms in (166)

Form Factors in 0(3)- Nonlinear o-Model

139

are omitted, the first term gives nothing because ((O^^HB(/3°)B(/3+)B(/3++ iri) is the eigenvector for A(/31) with the eigenvalue (163) and B1 UB1 does not contain /3i . The case 8i E B+ is treated in a similar way. Now apply the operator B(3n)P-1 0 to

(coil II BcQ°)Bc Q+)g (/3 + in) . The second term can be omitted because it does not contain Sri. As a result one has ((oil J B(P° ) B(P+)B(P+ + ri ) B(Pn)P-1,o

__ - 11

(P1 - P°)(P1 -,6+)(,61 - P+ - -001 -P - + ri )(Pj - P°) (P1 - Po + 2-i )(Pl - P+ + 2ari)(P1 - P+ + ,ri )(P1 - P- - ri )(P1 - P° - *i)

x 1((°II II 6(Po)g( P+)9(P+ + ai)sn

(168)

The following identities hold:

((011

B(Q°)BcQ+)BcQ+ + iri)! (Q1 + 2ai)

_ ( -ai) 11

(Q1

-,0- + 2iri)(Qi - Q° + 7ri)

c/1- Q-)(Q1- Q

x B(Q+)BcQ+ + ai ) P +EB+

I B-\P

( 1

fl_ fl

0)

PEB- PII

2 i

B(Q°)

uB°

1 (/3 - /3 - 21ri Q1

-

Q

+ 2 7ri I J E B o \ )3 - Q° - Ti )

-2lni\ + E BII P EB°

°\P

^

((Oil

8 -6 - 7ri 0

x Q1-Q +ir iBO \# ( Q - Q °

B(Q°) II B(Q + )e()3+ + ii) B+uP

Q - Q - - ir i Q -+7ri ) ,

)B-^ Q -

(169)

whose validity follows from the observations. The LHS and RHS are both rational functions of /31 which decrease for ,Q1 - oo and have n(B-)+n(B°) simple poles and whose values at the points /31 = /3- - 2iri, /31 = /3o - 7ri coincide. Transform LHS of Eq. (165) using (168) and RHS of (165) using (169) and use the identity ^(B ,Qu1B°, Q1 + 7rilB+) = - 2(7ri)2 11('61 -,3- - 7ri)(Q1 - /30 - 7ri) x (fl, -)3+ + 2iri)(Ql - Q° + 2ai)^(B1, Q1 + ai l B° I B+)

Form Factors in Completely Integrable Models of Quantum Field Theory

140

following from Lemma 3. As a result the proof of Eqs. (165) reduces to the proof of the identity: O(B ,,61 + 7ri I B° I B+) =

jj(,a1 - Q+ + 7ri)(/31 - Q° + 2wi)

x { -2(7ri)2 E ^(B , /3IB°\l3IB+) /31 PEB °

(Q - f3° - 27ri

x T7

-

1 8 +29ri

)(0 - 0° + iri )(f -,6- - 2iri )(j3 - Q+ + in ) (/3 -

B +,B-,B °\P

iri)

1 + E ^(B IB° U,QIB+\Q) /^ PEB+ M1 - l3 + vi

x 11

1 (/-go +'i)(/-Q+)

(170)

From the very definition of 4 it follows that , considered as a function of /31i 5 ( B- U /31 IB°IB+) is a polynomial of degree n(B+) + n(B°) - 1. This is why it is sufficient to prove that RHS and LHS of ( 170) coincide at the points /31 = /3° - 2ai , 33I = /3+ - ai . This fact follows immediately from Lemma 3. Consider finally w1 = 0, w ,i = 1. Eq. (157) reduces to

((Oil E H 8(P°)8(P+)B(i+ + xi)m(B-IB°IB+) l B=B-UBOUB+ x

(P+

-

P-

+ Wi)(

P+

-

(P+- P- - *i) P ° )(P - P °)( P+

P - )( P O

-

PO

-

a i)

P0^1

Pn=^1

+ai

ljg(P °)g(P+)d(P++,.i)m(B- IB°IB+)

E

=((Oil

-

(B\9j„eh )= B- U B° UB+

(P+ - P- - ai)

x 11 (P+ -

n-1

P

+

xi )(P +

- P°)(P -

P°)(P+

2xix(Pl + ,ri) " II Pl - P; + zxi A( ,Ol + Pl - Pj

S-(S -)2 -

P -)( P° =7 - ,ri)

1 n

(171)

It can be shown that in LHS only those terms are essential in which On E B+, Yl E B- or B°. The accounting of terms with /3n E B+, /31 E Bleads to the replacement in RHS of A(l31 + 2iri)C(/31 + ai) by .A-1(/31+

Form Factors in 0(3)-Nonlinear o-Model

141

iri)C(/31 + 7ri). To transform the LHS for /3n E B+, #1 E B° one should use the identity

lim (0II8(P1)II 8(P°)g(P+)g(P+ +xi)13(Pn)13(Pn +ri)Po,1 ((°IIS (Sn )2 fl 8(P°)( (P+)g(P+ + xi)

(Pi - P° + ri)2(Pi - P- + *i)(Pi - P+ + 2ori)(P, - P+) (Pi - P° + 2 ri)(P1 - P° - *i)(01 - P- - ri)(01 - P-)(P3 - P+ + 2xi)

(172) whose proof is similar to that of Eq. (168): operators B should be applied to ((011 in the order they are written in LHS of Eq. (172). Note that it is impossible to use Eqs. (161), (162) here since an indeterminacy appears: in Eq. (172) the multiplier (fan -,81 - in) is absent, in Eq. (162) one has for a = #1 zero in the RHS. Formula (172) is the result of uncovering this indeterminacy. To transform RHS of (171) one should use the identity

(01l rj 8((3°)8(0 +)B (Q + 7ri )C(/31 + in )

X ((011 2

E

11

8(a°)

PEB+ B °UP

xB( p

+ri )/31

H

8(/3+)

B+\P

1 (#- /3° + 27ri ) (13- ,Q+ + 2iri) -/3-ai )(a-!l +)

1

+

II°\P B(/3°) 11 ,R(,8+ + iri) al - (3

PEB° B

B+

x TT (Q - + + iri) (P - )13° + ai) # /x (N- /3 +-ini)(N-0°)

(173)

Equation ( 173) is not quite obvious ; let us outline its proof. Both LHS and RHS are rational functions of fll, decreasing for ,l1 -+ oo and having n(B°)+ n(B-)+n(B+) simple poles at the points f1 =,Q+7ri , 3 E B- UB+U B°. That is why it is sufficient to prove Eq. ( 173) at n ( B-) + n(B°) + n(B+) points . RHS has zeros at the point #1 = /3- - in. Among the commutation

142 Form Factors in Completely Integrable Models of Quantum Field Theory relations on elements off one can find the following:

B(^1)^(^2) - ^(r2)e(o1)

COr1 1

O2

(A(^1)D (o2) - A(o2)D(ri))

(174)

Let /3k = 61 + in, /3k E B-, and move C(/3k) to the left, successively using (174). We obtain zero because

((611

e(Q°)B(^+) g(Q+ + vi).A(Q) = 6 , Q E B

((011 II e(a°)e(a +)g(a+ + 7ri)A(p + ai) = 6 , a E B° .

(175)

Consider now /3k = /31i /3k E B°. In RHS one has

(176)

((611 11 g(a°)e(a+)e(a+ + jr,) II 131 - Ii'i + 7ri B°\Pk j#k In LHS one has

((611 II e(a°)g(a+)B(a+ + in)! (13k )C(ak + ii) . (177) B°\Pr

From Eq. (156) it follows that

B(,6k)C(ak +

7ri)

= •A(/3k)D(Qk + 7ri)

'I

(

j /3k - 6

+

mil

Substitute this identity into Eq. (177). The first term disappears by virtue of Eq. (175) and the remaining term is equal to (176). The case of 13k = P1 - 7ri, Qk E B+ is treated in a similar way. This completes the proof of Eq. (173). Let us return to Eq. (171). Transform LHS using Eq. (172) and RHS using Eq. (173) and exploit

^(B- I B° U ,61 IB+

U (al + 7ri)) = 2(7ri)2¢(B- I B° I B+ UP,)

x fl(,3 - a+ + 27ri)(,ol - 0° + 2r i)(,31 - 0- mni)(al - /3° - vi) .

Form Factors in 0(9)- Nonlinear a-Model

143

As a result the proof of Eq. (171) reduces to the proof of the identity

O(B

I B° J B+ U )31) = jj( /31 - Q° - iri)( /3

x{ ^(B PEB-

+ 2,r2 E

1/31B° U /3 I B +) a1 1

-

Q -) 1

(l3 - '80 - 7ri)(0 - ,8 -)

a

^(B- IB°\/3IB+Ul3)

1

(/31 -'0 - z•i)

PEBo

X II (a -,60 + 27ri)(/3 - /3+ + 2iri)(/3 - a° - ri)(8 - ,3- - ii) } /3- +ai) (178) which follows from Lemma 3 and the fact that ¢(B-IB°IB+ U /31) is a polynomial of degree of n(B°) + n(B+) - 1 with respect to /31.

Q.E.D. We have shown that form factors fµ, f°, fo,,, f satisfy Axioms 1, 2, 3 and thus defined some local operators. What are the properties of these operators? With respect to the Lorentz group the operators defined by f,.' and fµ„ are a vector and an (1, 1) tensor respectively, the operators defined by f °, f are scalars. With respect to the isotopic group the operators defined by fµ, f ° are vectors, the operators defined by f,,,,, f are scalars. The possibility of introducing the nontrivial operator of charge conjugation C in the space of states is connected, of course, with the possibility of introducing it in terms of initial Lagrangian formalism: Cn°C-1 = -n°. Evidently the Lagrangian is invariant under this transformation. The operators defined by f,,,,, fµ are even with respect to the charge conjugation operators f°; f is odd. The above facts show that it is plausible to identify the operators defined by fµ and f;,,, with jµ = ea6cOµnbne and T,,,,. This identification is confirmed by the following theorem. Theorem 3 . If operators j", T,,, are defined by fµ, ff,,, then

O.j a µ -

aµ 'µ. = 0 , Tµ. = Tmµ

(179)

and the operators P. = f°° Tµ0 (x1)dx1iQ° = f jo(x1 ) dx1 are the

144 Form Factors in Completely Integrable Models of Quantum Field Theory operators of energy-momentum and charge, which means PPZwl (91) ... Zw,. (/3n) l ph) n = M>2(ePi + (-1)µe-'i )Zwi (t1) ... Zw,.(Qn)Iph) j=1 QGZ.*,(/3) ... Zwn(fln)IPh) n

E(.S'a)wiZw* (^1)...Zw(Qj)...Zu,,,(Qn)IPh)

(180)

j=1

Proof. Eqs. (179) follow from the very definition of form factors. The proof of Eq . ( 180) is quite similar to those of Theorem 5 of Sec . 6; it is based on the explicit formulae for the two-particle form factors presented above. Q.E.D. The operator defined by fa is C-odd Lorentz scalar transformed under vector representation of the isotopic group . It is natural to identify it with the field na itself. Additional arguments in favour of this identification will be presented in Sec . 10 by calculating the singularities of commutators at the origin of coordinates . At last , the operator defined by f is C-odd Lorentz and isotopic . It is natural to identify it with the operator of the euclidean topological charge q = eabcc,,8,,na8„nbn ° which is the simplest operator of the kind. The norms of the form factors are calculated by means of formulae similar to (80 ), ( 125). For example, ((({0°}))n, (({0o}))n) = (O°(B IB°IB+))2 B=B-uBouB+

(a+

N

- - 7ri)

x ($+ - /3-)(N+ - )3°)(N° - /3 .)(Q° - N° - 7ri)(13+ -)3- + 7ri)

1 x (/3° -)30 - 27ri)(/3° /3- - 27ri)(/3+ - /3- - 27ri)(/.3+ - /3° - 27ri) . (181)

9 ASYMPTOTICS OF FORM FACTORS

The local commutativity theorem (Theorem 1 of Sec. 2) requires besides the validity of Axioms 1, 2, 3, 4 special asymptotic behaviors of f(,61,... ,8k,,6k+l + a,... Q„ + a) for o -> oo, which will be studied in the present section. The asymptotic for ITM will be considered in detail; for SG model only statements will be given; the asymptotic for NLS will be obtained from the ITM ones. We consider in detail ITM asymptotics, but not the SG ones, because of two reasons: first, proofs are more descriptive for ITM; second, for ITM more refined formulae can be obtained which will be used in the next section. Before we calculate the asymptotic of form factors in ITM let us prove some subsidiary statements. Theorem 4 of Sec. 6 implies for the limit t --> oo the following Lemma. Lemma 1 . Form factors fµ, fµ„ in ITM can be presented in the form fj,33

... , 82n) = [ (eP; _

(_1)µe -P;)^

LLL (( /^ fµ( /31,... ,/32n) = I^( e"i

[J (3 _ F'j)(Fn).

i<j

_ (_1)µe-P; )]

[J (,3i

- /j)

i<j x ((F.+). + 1)a(F. )n) , a = 1, 2 fpv(QI,.

,A2n) _

X

[>(e#i

_ (_1)µe-R 1) r(e^1

HC(Ni -

Qj)( Fn)n

i<j 145

,

L^J

_ (_1)ve-Q;

11

11,, (182)

Form Factors in Completely Integrable Models of Quantum Field Theory

146

where Fn( /31,...

(21ri) -n ,/'nlln +1,... ,12n ) =

nI

h( a i - aj ) lI 0 ( al, ... , a n la l, • • •

J dai...dan

flct(ai_Pi)

q qS , Nn 1)n +1, • • • 032n)

i<j Fn()31,... ,Nn l/n+l.... N2n) n

(an

=

+j - a j - 7r i)

F(,31 ,...

,, n

l,6n+l, ... , i2n)

,

j=1

F} n (81, ... , Qnfl lqq h'n+1:F1 , ... , Y2n) - (27ri)-n

n!

J doi... , dan I ca(ai - #j)

x II sh( ai -

aj ) Il }(al, ... ) an 191, • • • , , n+l INn +1:F1 , • • • , /32n)

i<j

Polynomials IIc(al , ... )an l.l, • • • An+c lµ1, • • • µn-c) are the determinants of the n x n matrices B j (c = 0 , ±) with matrix elements Bj =Ai-1(aj IAl,... ,An+cl/11 )... ,/ln-c),(2 < i < n),B, = Oc(aj) where the functions A; are given in Sec. 7, Oe(a) are arbitrary polynomials of degree (n - 1) whose senior coefficient is equal to 1. Later on we shall take for 4 (a1), c = ±, the following polynomials:

vi

(a)=

n

Ia

7ri

-,Uq+

q=1

2 I , \

n-1

/

q5 (a)= I a

/

-^1q-

q=1

7ri \ 2)

\

/

In this case the terms containing 8c -loi(al, ... , An-l), 8c,i°i(µl - 7ri, ... , Pn-1 - 7ri) can be omitted in the formulae for As (118), since their contributions to the 2-nd, ... , n-th rows are proportional to the first row. For further estimation we shall need the following representation of the polynomials W. Lemma 2 . Polynomials IIc(al,... , an 1a1, ... , An+c lµl, ... , µn-c) can be presented as follows:

det De ll '(al, ... , and.\l, ... , An+elpl, ... , Pn-c =

7ri II (ai - aj) i<j

(183)

Asymptotic* of Form Factors

147

where D` are n x n matrices with matrix elements n+c

DSj 11

n-c -1

7ri ai-Aq --

n-c

1

11 (ai q=1 m=1 q=m+2 ^

-{4 q)1: s=0 (

2s

+

1) !.

2s+1 m

= d

( 2 da ) n+c-1 n+c

, 1 f7ri d \ 2s+1

X IL 11 m=1 q=m+2

(2s + 1)! ` 2 dal

m

x IT(aj - A,) } - 7ribc oO°(a1)O(ai)

(184)

q=1

where q(aj) is an arbitrary polynomial of degree (n - 1) whose senior coefficient is equal to 1. Proof. Consider, for example, II+(al,... , an Jal, ... An+l lµ1, • • • , 14n-l). According to Lemma 1 it is the determinant of an n x n matrix with matrix elements n+1

_^( a, - ay - 2 Qi-z(ai - 7ril{41 - 7ri, ... , /4n_1 - 7ri) 9 =1 n-1 ^

( ai

-

l4 9 + xq

Q i(a1

dal, ...

I

An +1)

,

q

where the polynomials Qi are defined in Sec. 7, Eq. (119) Qi(al.Al, ... , Ak)

[ (a+!)'_ (a_!)

_

'J

(-1)iO-i-r(^1, ... , ak) .

1=o Let us multiply and divide II+ by the Vandermond determinant ( a l - 7ri) n-1 , (al - 7ri) n-2

det

(an - 7ri) n-1 ,

(an - 7ri

,. . . . ..

1

185

( ) ()

Form Factors in Completely Integrable Models of Quantum Field Theory

148

We obtain

II+( a l, ... , CY n111)

1 l ... , n+1 /1 1 , ... , µn-1 )

det D+

=

7rtn(a{-aj) i<j

where

=n( ^i)

Q„+(aj - ai lp1 - ai, ... ,

V t aj - ay - 2 g=1

mcl n-1

x µn-1 - ai)(ai - ai)

n-m-2

+ 11 (aj - Pg + 2 4=1

n X

Q.(aj

lal. ..... n+1)(ai - iri) n-m

.

m=1

Thus we have to show that -1 kr

k-1

k

lvl, ... , Vk)a2- 1-"'

= L^ 11 (a2 - v9) m=1 m=1 9=m4-2 Qm(al

2s+1 m

x

11(al - v9)

(2s + 1)! (2 dai)

S=O

(186)

g=1

Let us prove this identity . Notice that Qm can be presented as follows: m 1 7ri -1 [mom [[ Qm(al lvl , ... , Vk) = LL (2) I1 - (- 1)l]C,l,ai 1 = 0 u= t

X (-1)m-uOm-u(vl, ... , vk ri 2s

= 2) s=0 C

+

1 1

(2s+ 1)!

d 28}-1 m

(dal )

Qm-u(v1,... , vk) , u =0

hence k-1 k-m-1 ai 2s+1 1 E Qm(all v1 , , .. , Vk)a2 = (2 (2s + 1)! m=1 a=0 p-1 d 2s+1 kk- k--p x (dal )

E E CIP, 2 -1) p=1 q=O

k-P-9-1Qk

- P-9-1(Vl, ... , vk) .

Asymptotica of Form Factors

149

Now we have only to use the identity k-lk-pp-1 aga2(-1 )k-p-q-lOrk-p-q-1(v1) ... , vk) p=1 q=0 n-1

m

k

- vq) ft (a2 - vq) .

E Mal M=O q=1 q=m+2

The proof of the last identity is not very complicated but a beautiful combinatorial problem which we leave to the reader. Thus the representation (183) for 11+ is proven. H- can be considered in a similar way; to prove Eq. (183) for II0 one should replace the first column of the Vandermond determinant used by 0(a;), i = 1,... , n. + Remark 1. The series of the type sEo 2s+1 , ( 1 da)28 1 g11(a - vq) encountered in Eq. (184) terminates. Evidently 00

7ri d

2s + 1

=1

ir i

7ri d

d

(2s ± 1)! ( 2 da) 2 Cexp ( 2 da) - exp C

2 da))

and consequently 00 1

ai d

2s+1 m

-) H(a - vq)

E (

2 da )! \Cs=0 2s + 1. 2

HC

q=1

-n(

7ri

a-vq+- a-vg-21) 2)

q=1

q=1

Remark 2. From the proof of Lemma 2 it follows that ordering of the sets {a} and {p} is of no importance. For example, in the expression n--c 7ri 2s+ 1 1 q=,+2(ai

d 2s+1 m

Cdaj) ^(ai - µq) - µq ) > (2) (2s + 1)!

all µq can be replaced by µ.wlgl, where in is an arbitrary permutation. The asymptotic behaviour of f (fl1, ... ,13k, Qk+l + o,,... , ,62n + o) is described by the following theorem.

Form Factors in Completely Integrable Models of Quantum Field Theory

150

Theorem 1 . Consider the form factors fµ, fµ„ in ITM. Denote by g° and g the following functions: 9 3(/31,...

,N2n) =

]I C(13i -

6j)(

F3)n

i <j

9°(Q1,... fl2n) = IJ((Ni -Qj)((Fn )n+ (-1)a(Fn )n) , a = 1,2 , i
9

(0

1, - .. r,62n) =

[JC(Qi - ij)( Fn ) n i<j

which are connected with fµ, fµ,, by Eq. (182). The following asymptotic holds : let /31 i ... , Qk be finite while Qj for j > k + 1 are equal to $ + a, / being finite quantities and o -> oo, then

9a(01, ...

,62n) = 0

0

k-1(mod2), exp ( 4IcT)

9(/11, ... 062n) = O a-' exp I 4 jojI 1 , k =- 1(mod 2) , 9(/31, 9°(Q1,

... , fl2n) =

O(0,- 2 )

... , Q2n) = 27r0'-

k-0(mod2),

,

leabcgb

(01, ... ,

Pk)

X 9e(&+1, • • • , Q2n)(1 + O(0'-1)) , k = 0(mod 2) . (187) We have presented in explicit expression the principal term of the asymptotics in the last formula as it will be important later. Proof. Notice first that we can limit ourselves to the consideration of the case k = n. In fact, suppose we have proven Eqs. (187) for k = n. Then using Eq . ( 110), we get res g (,Ql, Q2, ... Q2n) = 9(/33, ... , Q2n ) 0 (e1,1 ® e2,2 - e 2,1 (9 el,2) X (S(f2n - Q1) ... S(f3 -,61) /- 1) = /^^ 9 (/33, ... An) 0(el,l

0

e2,2 - el,2

0 e2,1)(S(fn - 81) ... S(/33

-

01) - 1 + O(t _l)) in. N2 =Nl+7ri

Here we have used the asymptotics S(v) = 1 + 0(o,-'). The asymptotics of the LHS have been assumed known, so that g(/33i ... , Q2n) also has the

Asymptotics of Form Factors

151

required asymptotics (the operator 1-S(,Qn-,81) ... S(,Q3-,Q1 ) has no kernel independent of f31 i the latter being arbitrary). The case 12n = , 02n_1 + 7ri can be treated in a similar way. Thus we can obtain from Eq. (187) for k=nEgs.(187)fork>nandk 0 and consider the function 93(#,,.. . q g3: /^ (188) ,82n) _

JT C(pi - /3j)(F3)n •

i<j

For the form factors in ITM the combination of exponential and power behaviour is characteristic. Consider, at first, the exponents. The function C(/3) has the following asymptotics:

y^2-* exp 14^ Q^ (1 + O(/-1)) , hence 2n

n

2

11C(Qi-

(3j)^' (2 l

)

i
2n

, e -11(( Qi -)3)

i<j

11

C(1ii-/j) •

(189)

i<j
Let us now turn to (Fn)n. From the very definition it follows that E (OI fJB(,8jp)F(I3il,... ,fli.Ij..... . IQjn)

(Fn)n =

{1...2n}={il ...i,.}U{jl...jn}

X

11

1

(190)

(j

The factors IIB(,3j,)II(,Qi, - 8jq)-1 give only power contribution; that is why we have gonly to estimate the exponential behaviour of

F3(,li1) ... , /i„II'j1,...

,)3;n)

//^ = (E(/3 , - A, - 7ri)) F(Ni1, ... , ,3i,.

IQj1 ... ,,8jn) ,

where F is the determinant of an n x n matrix with matrix elements ' zn 2- 4Jdft ( a_/3i)Ai_i(aIfli1,... fli. INj1 7 ... , Pjn) j-1

xexp(n+1-2j)a, i>j 2-

2-P-

2n

.Fl; = 7ri Jdaft(a_

/3i) (a) exP(n+

1_2i)a,

j-1

where q( a) is an arbitrary polynomial of degree n - 1. Ai and 0 are polynomials, which is why the exponential behaviour of the integrands is

152

Form Factors in Completely Integrable Models of Quantum Field Theory

determined by ^p(a - i3) and exp ( n + 1 - 2j ) a. The function ^p(a - /3p) behaves for a -^ ±oo as follows: ^p(a - ap) = 21 exp (_ia - QpI) a-#(1 + O(a-1)) We can estimate this roughly by the principal term of its asymptotics. Consider three regions on the real axis : a < /3 j , j = 1.... n; ,Qi < a < /3i, i = 1,... , n, j = n+1, ... 2n; a > /3i, j = n+1, ... , 2n. The exponential behaviour of the integrands in these regions is described by exp((n + 1 2n 2n n 2j)a + 2na - E /i ), exp((n + 1- 2j)a - E /3j + .E Pi ), exp((n + 1 j=1 j=n}1 7=1 2n

2j)a - 2na + j E 1 6j) respectively. The first exponent is always an increasing one, i .e. it decreases for a -oo; the third exponent is always a decreasing one, i .e. it decreases for a -> oo. The second exponent is an increasing one for n+ 1- 2j > 0 and a decreasing one for n+ 1- 2i < 0; for n + 1- 2j = 0 the exponential behaviour in the intermediate region disappears. These estimations show that for n + 1 - 2j > 0 only the vicinity of a = tr gives n significant contribution to the integral; H ^o(a - lap) can then be replaced p=1 by its asymptotics r.j 2' a-Il eXP - 2I f 1) o) 1 (G2 tai

I

0000

di

2n

x ^P(& - Qp)eXP n +1-2j iY ((2 p=n+1

x Ai-1(i••r+-1fli..... . Pi. 1Qi..... . Pi,.)(1+O(o-1)),

n+1 -2j > 0.

We have denoted O(a) by Ao(a). For n + 1 - 2j < 0 only the vicinity of zero gives an essential contribution to the integral fii = 2 2 o- 2 xexp(-

l

1

oo

n

\, 2 1+1-2j)a) 2 / tai,/ °°dafJ`p(a-/p)eXp p=1

x Ai_1(ajfi1,... ,Pi.I)lil,... ,/i,.)(1+O(a-1)) , n+1 -2j < 0 . Finally, for odd n the case n + 1 - 2j = 0 is possible. For this j we have for .Fi,i a plateau between the points 0 and a, which is estimated as

Asymptotics of Form Factors

o

1 - (-na\

_

7'j

2'2aio

exP

2

153

A i- l(a I 0i17...

,Nijfl11,...F3i,.)da

0

x (1+O(Q-1)) , n+1-2j =0 Hence, for n = 2k the full exponential contribution to the asymptotics is k

exp((k2+jE1(1-2j))a) = 1, for n = 2k+1 the full exponential contribution k

is exp((14-(2k + 1)(2k + 1) - Z (2k + 1) + jE1(1 - 2 j))a) = exp(- 4 ). These results are in agreement with Eq. (187). Let us now estimate the power contribution. We consider only the case n = 2k which is the most interesting. For n = 2k + 1 the form factor decreases exponentially. The above reasoning implies 2k

det Jr - e-k

° 01

-20

1

J da i... dakd& i ...d&k

^7ri

4k

k 2k /

111

(ai - 3)

k

II alai-

gyp)eXP

i 1 =1 p=1 p=2k+1 X

H

0

(al) ...

,a k, 51 1 + a,... , &

1=

+ a l,ail....

))3i^.IN7i^... ,/3k)

(191) where II° is given by Eq. (183). Our main purpose is the estimation Of 110 (al, ... , a2k IA,.... ) A2k Ip1, ... ,µ2k) for the case al, ... , ak ^- 0, ak+l, ... , a2k ^ ' a; the set X11, ... , A2k, /L1, ... µ2k is divided into two subsets both containing 2k elements, elements of the first subset being - 0, elements of the second subset being - a. More concretely, let al, ... , Ak+p 0, Ak+P+1, ... , A2k - a, 111) ... , Pk-P '" 0,µk-P+1, ... , µ2k -. a, p being an integer such that I pI < k. For the sake of definiteness we consider p > 0 also. 2k-1

Let us use for H° the presentation (183), taking - 911 (aj - /19 + 2) for 2k

0(aj) and H (ai - a9 - z') for 0(ai). The matrix appears to be divided 9=2

into four blocks:

D° =1 D1 D2 V3 V4

Form Factors in Completely Integrable Models of Quantum Field Theory

154

The matrix elements of Dl and D4 have the following asymptotics for it -+ 00: D = ^zk

k+p vi k-p ( ^i l 2a+1 TT (a^ - aq - 2) 1 II (ai - µq) 2 qq=11 8=0 m=1 q=m+2 )

k -p

2a+1 m

d

iri

Mai - µ9) + I (aj - µq + 2 )

x (2s + 1)! (da •)

d 2s+1

k+p Ai 2s+1 1

x

E J1

(ai - J^

_m m=1q m x JI(aj -

q) a_

(2s + 1)! . (day )

(2 )

i < k, j < k ,

Ag - iri)(1 + O(tr-1)) ,

q=1

2k

Do

2k

2s+1

or2k (aj - aq - iri) > H - . U , ) m=1 q=m+2 8=0 q=k+p+1 d

23+1

2k

(aj - µq)+

x (2s + 1)! ()

q=k-p+l

11 (aj -

µq

+

2)

q=k-p+l

2s+1

2a+1

x (ai - Aq) 2 ) m=1 2k q=m+2Cri a=0

(2s + 1)! (daj )

m

(aj-Aq-7fi) (1+0(ir-1)),

i>k,j>k

q=k+p+1

From the matrix elements of the blocks V2 and D3 we extract only those terms which increase faster than a2k-2. They originate from the terms 2p-2 2k

2s+1

7ri

D - E J (a' q + ) ( "i) 2 m=1 q=1 a=0 2a+1

m

2k

(2s + 1)! 2k-1

d •) fl(aj -)1q) 11 ( ai - Aq - 7ni ) - t (aj_uq+) X (da q=1 q=m+2 q=1 2k

x

[J(ai - Aq - li) + O(o 2k -2 ) , q=2

7 < k, i > k ,

Asymptotics of Form Factors

2p-2 2k 7ri 2s+1 1 r l (cu•-A q

'j - III

D°--

155

2)

m=1 q=1 8=0

\21 (2s + 1)!

28+1 jm 2k 2k-1 d ) X (da

^ (ai - µq) - I (aj - Pq +

11(aj - p.)

q=1 q=m+2 q=1

21

2k

x

jj(ai - .\q -

1r i)

+ O(tr 2k -2) ,

j > k, i < k

q=2 2p-1

Notice that D° is in this case of the form E 1 f^ g;'+O(Q2k-2) where f^ trk+p. One can transform the matrix D°, taking the linear combinations of columns in order to obtain in the changed blocks D2 and D3: 2p-1 frngm

(D2)ij = m=j-k 2p-1 (D3)ij =

fj g{' . m=j

In the course of this transformation the estimation O(0.2k) for the matrix elements of b, and D4 is preserved. Now the dependence on ai can be extracted precisely in D2i D3: (D2)ij = a'nP(

j)(Q)

m=0

amPm)(a)

(D3)ij =

m=0

where P,(nj), P,(„j ) are polynomials which depend , besides a, on aj, A, µ, though this dep endence is not essential for our purposes . The polynomials P,(,{) (a) and P,(j )(a) have the degrees 2k + 2p-(j -k )- 1 and 2k + 2p- j -1 respectively. Let us add to the second column of the determinant the first column multiplied by -Po' -1 to the third column - the second column multiplied by P(3)( tr)[P12 ) - Pi0(Po1))]- 1 and the first column multiplied by Po3 )(o)[P0 ( a)]-1, etc ., up to the k-th column. In the course of this process the asymptotic behaviour of D1 remains unchanged while the first (p - 1) columns of V3 change their asymptotic behaviour to

156

Form Factors in Completely Integrable Models of Quantum Field Theory

01 2(1+P-i), 7 = 1, ... , p - 1; other columns of D3 still behave as O(o2k). A similar operation can be carried out with the task k columns of the determinant, whose result is: the first p - 1 columns of D2 are O( o2(2k+P-i)), other columns of D2 and all the matrix elements of D4 are O(o2k). Hence detDo = 0( 0,4k2+2P (P-1)) .

Consider in more detail the cases p = O, p = 1. For p = 0 the block D3 is O(o2k-2), hence D° = o4k2

det

[(det D1 + 0(o,-1))(det D4 + O(o-1)) + O(o-2)]

where D1 is a k x k matrix with matrix elements k

(Dl)ij =

ft

( aj -Aq-

)

2

- µq q=1 m=1 q=m+2 s=° d

x (da)

2s+1

O

m

k

1 (2s + 1)!

7ri

fi(aj -pq)+jj (aj_pq+--) q=1

ire 2s+1

x

2s+1

)

2 Y_ 11 (a;

q=1

1

d

2 (2s+1)!

2s+1 m

( da; )

TI(aj -µq) • q=1

The matrix D4 differs from Dl by the replacement al -4 ak+l, Aq

. Ak+q, µq ' µk+q

For p = 1 the block D3 is O(o2k-1); the block D2 is O(o2k). Consequently a

detDo = .4 k detD1(al,... ,ak I A1, ... ,Ak + 1 Iµ1) ...

µk -1)

x det D-1(ak+l, ... , a2k IAk+2, ... , azk l At, ... , µ2k)(1 + O(o-1))

Matrices De are given by Eq. (184). The case p < -1 can be treated in a similar way. One has detDo = O(Q4k2+2P(P+1))

For p = -1 this formula can be more precise:

kl Al, • • • , 14-1I µ1, • • • , /6k+ 1) x det Dl (ak+1, ... , a2k Iak) ... , A2k I µ 1+2, ... , µ2k)(1 + O(0' -1))

detDo = - Q4k^ det D1 (al, ...

)Cr

157

Aaymptotica of Form Factors

Substituting these results into Eq. (191) one obtains k2°trk2+ 21)2

det.F = O(e2 k2 e_k2°Ok2 det.F =

X det.T

(192)

-2 ) , (IpI > 1) .

detF+(f11 ,...

(Nik +2) ... ,fit2k

Pi

(j (^ ,iik+l A l)... Pik -1)

k ,... ,

fi72k)( 1+ 0(O -1))

,

p = 1 (193) where /ail det

....

) Ak

+1 , /3

F-2k2e -

j1) ...

k2°Ok2d et

x det F+(aik)...

) /"

j k -1 '"

0) Y ik}21

.F- (fi1....

,/" i2kl/,k +2

)...

.. ik

... ) i2k ) #jk) ... 03j2k

-llajl,... ,f3j

-

or)

k +l)

, Nj2 k )( 1+0(O -1)) ,

p

- -1 .

(194) The case p = 0 is to be considered in more detail . We have obtained the formula

II°(al)...

,a2kl)il)...

1

2

,A2kIP1,... ,

µ 2k)

03k i<j

(ai

^ (detDi

- aj)

{ O(tr-1)) al 1 a') (detD2 + O(O-1)) + O(O-2)1 k
The determinant of Dl for example, is transformed to the determinant of a k x k matrix with the following elements: rj

(

aj

- A9 - 2 Qi( aj - 7ril{ll - 7ri, ...

µk

- Sri)

4 k ai +r (ai q+ Qi(ajI i,...,Ak),ij =1,...,k. 9=1

Recall that

Qk(alvl ,... ,vk

a - vy - 2z I ^ I a-v9+ 2Z I q

158

Form Factors in Completely Integrable Models of Quantum Field Theory

hence in the last row of the determinant one has (a3-Aq- 2t) q

C

ad-µy- 7ri 2)

(aj -Ag+2) (aj _pq+) q

Usual arguments which make use of the identity

2

cp(a - 2ai) _ sp(a) a 3

ai

2

show that the last row vanishes after the integrations in (191) over eel.... , ak are fulfilled. The same happens to the last row of det D2 after the integrations over ak+l, ... , a2k are fulfilled. Hence

detF = O( e-k2v01 k2 - 2 ) , p = 0 . (195) Now we have to collect all the above facts together. Consider Eq. (190). The operator B(r) can be written as follows: B(o) = Bl (rr)D2(r) + Al(r)B2(r) ,

where A1i B1 and D2, B2 are constructed via Eq. (111) through the first and the last 2k particles respectively. Let r - 0, then D2(r) - 1, B2(r) _ O(o-1), hence

B(r) = Bl(r) + O(,7-1) . (196) Let r - a, then

B(r) = B2(r) + O(v-1) ,

(197)

where r = r - O, B2(T) = B2(T I/I2k+1, ... , L) -

Consider a fixed term in Eq. (190). Let ,13i1, ... , Qik +p, )3il,

)3jk-p - 0

Nik+p +l, ... f I3i2k f Pik-p+1 f ... , '832k - v, then

2k

k+p k - p 1 2 _-2k2p 2 1I 1I

s,t.1 ^i• - Qls

2k

2k

1

a=1 t=1 07s 9=k^+^p+l ack^-^p+1 fl'9 - I3.

(198)

Asymptotics of Form Factors

159

Combining/^Eqs. (192, 195, 193, 194, 198, 197 ) one gets (F3)2k(Ql, • • • ,Q4k) =

2k'o.-le-ksa0.

p -kslrf(F+)k(Q1, • • • Q2k)

x (F )k(Q2k+1, ... A k) - (F )k(Ql, • • • ,Q2k) x (F+)k(Q2k+1, ... , Q4k)}(l + O(0'-1)) .

Substituting this in (188) and using the asymptotics ( 189) one obtains finally q1, 93(Q...

2a 3bc e a

,••• rNn)

x 9c(Qn+1,... ,+O(a-1)) & )(l The power contribution for n = 2k + 1 can be obtained in a similar way.

Consideration of the functions g1, g2, g involves no additional difficulties. Q.E.D. Let us present without proof a similar theorem for SG model. Theorem 2 . The functions g+, g- in SG model have the following asymptotics for Ql, ... , Qk ^' 0, Qk+1, • • • , Q2n - 0, o -' oo: 9+ (Ql , ... , Q2n) = O

9-(Qi,•••,Q2n)=0

exp

a 1 4^ Q - 40)

) a 1 exp -4fv-- / , 40

9+(Q1, ... , Q2n) = O (exp ( -2 min 9-(Q1, • • • , 02n) = 0

(

k- 1(mod2),

1,

/ a exp (_2min 11, ) v I I , k - O(mod 2) .

(199) The asymptotics in NLS can be obtained as a corollary of Theorem 1. Theorem 3 (Corollary of Theorem 1). Consider form factors f, fµ", fµ, fa in NLS . Introduce the functions 1 9a(#1,... ,Q2n) =(E chOj)

fl(#I)... ,Q2n)

2 9(Ql,... An) _ ChQj)

9(91,

... , #2n+ 1) = ((chj x

f (Ql, ...

f11(Ql,... ,Q2n) ,

)2

, #2n+ 1)

\ shflj 1 2 - 1)

-1

160

Form Factors in Completely Integrable Models of Quantum Field Theory

Let ,Ql,... , Qk ^' O,,Dk+l, ... , N2n ^' o. The following asymptotics hold: /^ 27r /p-^ 7 Eabc9b (N1, • • • , /3k)9c(Qk+1) ... , N2n) 9°(Q1, ... , f2n) 01

k=0(mod2) 9°(P1, ... ,N2n ) -

011

Eabcfb (P1, ... , fln)fc($k+1) ... , hl2n)

k - 1(mod 2) /^ 27r //^^1,... ,Q2n+1) ^' f°(/'

q1 Eabcfb(/31i... ,,6k) 9c( h^k+1 ,... ) ^2n+1)

k-1(mod2), ,,62n+1) ... 21r Q

Eabcgb qq q (Ni, ... , f k)fc(&+1, ... , ^2n+1)

k = 0(mod 2) ; 9(fl,

... , N2n) =

O(0' -2)

,

(200)

where ,13j =/3i - a. The form factors in NLS are expressed in terms of elementary functions; that is why Eqs. (200) can be nicely illustrated by explicit consideration of the few-particle form factors. One can get from the general formulae of Sec. 9 the following results: '$`N12 +7ri) el-1 - e-1,1) PA) = 1, 93(Pl,F'2) = 1th21312 R 4 8 2 )312(012 + 27ri)

f3()1, #2, Q3) =

1 11 th21 fli (/3ij + 7ri) 7r2{-(/313 + 27ri) 2 Qij (/3ij + 27ri)

16 i<j

x (eo,o,o - el,o,1, -el,o-1) +,Q12(eo,o,o - el,-l,o - e-1,1,o) +,Q23(eo, o,o - eo,l,-l - eo,-l,l)} , where lij = Ni -,3j. In the next section we shall need one more asymptotic formula. Consider the form factor fµ (/31, ... , N2n). Let /3 < ... < ,Q2n and denote ,6i+l-/3iby L. We have shown that fµ(01i ... ,82n) =E ( e'3i _(-1 ) Me-L;) 9°(Q1, ... ,Q2n ), where g° is invariant under simultaneous shift of rapidities, i.e., g° depends only on Al, 02, ... , 02n_1 . We are interested in the behaviour of Ilg°(/31i... , /32n)112 when all Ai's are large.

Asymptotics of Form Factors

161

Theorem 4. The function Ilga(Nl, ... „Q2n)112 in ITM is characterized by the following behaviour for n p

Ilga(h'1,... ,/32n

112

(

n-1

2p2 l exp

..' II

p=1

_x2^i )

II

O 2p

(201)

p=1

Sketch of the Proof. According to the remark made the end of Sec. 7 one can present IIg3(/31, ... , )32.) ll2 as follows:

IIg3(al , ... , /32n)112 -

x (F3(ai"... X /^

laj],... ,ij.))2

1 ,

/^

p,q (NJp - Niy )(^Jp - ^iq - 7rt)

where the function F3 is presented in Lemma 1 . The main difficulty in obtaining on estimation for (201 ) lies in the estimation of F3 (/311,... IQjI,... ). The method of estimating F3 is similar to that used in Theorem 1. One should separate , at first , the exponential contributions . Having done that , one should make sure that the integral over aj (j = 1, ... , n) is mainly concentrated on the segment ,62j_1 < aj < /32j (we supported the /3 's to be sufficiently separated ). Then the power contribution should be estimated . Corresponding calculations are very cumbersome and do not differ radically from those made in Theorem 1. We present without proof a similar Theorem for SG model. Theorem 5. The function Ilg±(,01, • • • 032n )112 in SG model behaves for Ai - ai+1 >> 1 as follows:

Ilg±(al, ...

, /32n

)11 2

fJ exp (_

2_1

p=1

-

L 2-1)

11 exp

p=1

Finally, for NLS the following estimations of

( (

- min 2p/ 2,

11fal1 2

and IIgaI12 hold.

(202)

162

Form Factors in Completely Integrable Models of Quantum Field Theory

Theorem 6 . The functions > 1 as follows: i+1

,6 - ai

I If ° II 2

and

I Ig° I I2 in NLS behave for

Di

2n-1

IIgd(p1, ... , #2n)112 = [

A;2

1 P=1

q 12n Ilf a (f1, ... , N2n = 2 IJ p=1

+l II2

O; 2

(203)

Sketch of the Proof. According to Eq. (181), IIf3(31,... be presented as follows:

, )11 2 13n

can

2 r2

IIf3(P1..... Pn )112 =

rj th41 (Pi i<j 2

(Pi - dj)2 (Pi - Pj)

+ P° - ,ri) ° - ° - , E (m°(B IB°IB+))2 I (P+o (P - P-)(P P)(P P-)(P P ri) X a_a-ua o ua+ T7 1 x 11(P+- P-+,ri)(P° - P° - 2,ri)(P° - P-- 2wi)(P+ - P-- 2ai)(P+- P° - 2,ri)

The main difficulty lies in the estimation of ^°(B-IB°IB+).

For these

determinants one can write formulae similar to (183), multiplying and dividing them by the Vandermond determinant II (,Qi - ,0j). When this is i<j

done the estimation is reduced to complicated but rather straightforward calculations.

10 CURRENT ALGEBRAS

The present section is devoted to the calculation of the singularities of commutators at the origin of coordinates. We consider the following operators: jµ in SG, jµ in ITM, jµ in NLS. Let us recall several formulae from Sec. 2. Suppose the operators O(x) O(y) are defined by the form factors fl, f2. Then there are two equivalent forms of matrix element of )x-ix(B)y (A IO(x)O(y )I B)+eix(A

S(AI A1) A=A1uA2UA3 B=B1uB2UB3

xS(A2UA3IA3)

00 .(C)=O

J dCf1(A1+i0ICUB2)S(CIA3UC)

x f2((C U A 2) - i01-91 ) exp(i(x - y)(,c(C) + i (B2 ) + ic(A2) + ic(A3))) (204) 1I B) , x O(A3i B3)S(B 31 1i2 U (A I0(x)O( y)I B)- eiK( A )x- iI(B)y = S(A IA 2) A=AIUA,UA3 B=BIuB2uB3 00

X S(A1UA 3IA3 ) .I(C)=O

J dCfl(A1-iOIC U B2)S(C UA' 316)

x f2((C U A 2) + i0i B 1 ) eXP(i(x - y)(K(C) + i(B1 ) + ic(A3) + ic(A))) O(A3i B3)S(B 3IB1 B3)S(B 2I B) . 163

(205)

164

Form Factors in Completely Integrable Models of Quantum Field Theory Lemma 2 of Sec. 2 states that

(AIO1(x)O2(y)I B)t = (A101(x)02(y)I B)To prove the local commutativity theorem we have written the convolution f [O(x), O(0)]dx in the form (A

l

J

[O i (x), 02(0)] exp(ix (A)x)'o(x) dx1 B )

= J (1A1O1(x)O2(0)I B>- - (A102(0)01(x)I B> +)e`(A)x,P -( x )dx + J ((1 101(X)02(0)1 B )+ - (A 1°2(0)O1(x)1 B) -) e"`(A)x
J fj(X1+i0Ic'UB2)S(CIA3U C)f2((CUA2)-a0IB1) x So- (ic(C) + c(B2) + K(A3) + ?(A4))do where o E ;j C E yEC-Y, 0_ is the Fourier transform of tp_ . Function tp_ (,c (C) + ...) decreases faster than an arbitrary power of a-° for o -• 00, if cp(x) vanishes with all its derivaties at the point x = 0. This is why it is sufficient to require that fl, f2 do not increase too fast for o -+ oo. Evidently the asymptotics (187), (199), (200) satisfy this requirement. But as we intend to study the singularity of the commutator at the origin of coordinates we have to use the functions tp with a different behaviour at the point x = 0. Here some new possibilities arise. Let us discuss one important circumstance which has been ignored until now. Dealing with the expressions (204), (205) one has to make sure that the integrals and the series in Eqs. (204, 205) are convergent. Actually, very rough estimation of the form factors guarantees the convergence. Consider, for example, the operators T,,,,, jµ in any model discussed in this book. The form factors of these operators can be presented as follows: f(B) = (po(B))K(pl(B))'g(B) ,

(207)

where ic,1 are certain integers (for example, rc = 1 = 1 for To,), the function g(B) satisfies the condition

g(B + o) = g(B) •

(208)

165

Current Algebras

Let us suppose that the function g allows the following estimation:

Ilg(A - in, C - 2 , B)II

< Cn(A)+n(B)+n(C) J cth 1 ( a (209) aEA l3EB

where C is some construct. Consider now the expression (205) for x < y. It is possible to move the contour of integration with respect to o, _ >7EC "Y to the line Imo, = I. . Then , using the estimation (209), one can easily get the following estimation for the matrix element:

t(A3, B3)

I (A IO(x)O(y) I B) I ? A=A,UA2UA3 B=B1uBsuB3

') (a -3)Cn( A1)+n(A2 )+ n(B,)+n(B s) X [J cth aEAluA2 QEB1uB2

)K1 d x (Ipo(Ai) - po(B2 )I + (1P1 A1) - pi (Bl) I + dy x

(I

d

o( A 2 ) _o(Bi)I+ dy/l

"'

(1P1A2_P1B11+

d ) 13

x exp (C1CZKo( m(x - y))) , (210) where KO is the following function: exp(-x ch j3)d(3 .

Ko(x) = j

Thus, if the estimation (209) holds the expression (205) for the matrix element is finite for x > y (similarly (204) is finite for x < y). When x approaches y, the matrix element can be singular but the estimation (210) proves that the singularity is of power character because the function Ko(x) behaves for x -> 0 as follows: Ko(x) = -2lnx +... , x --+ 0 . As to the estimation (209) it looks quite natural. The author proved it for SG in the reflectionless case. The investigation of the estimation (209) in the other cases encounters many technical problems but the author believes that they can be overcome.

166

Form Factors in Completely Integrable Models of Quantum Field Theory

For a detailed study of the singularities of the commutators at the origin of coordinates one needs some refined information. Some experiments and general reasonings have convinced us of the validity of the following statements which are formulated as hypotheses , since their rigorous proof is still lacking. Hypothesis 1. In SG model and ITM the series 00

IIg(V)II2dVo

, > J

II9a(e)112 dcVo

(211)

n(C)=0 n(C)=O

converge (the convergence of the integrals f IIg(C )II2d C o follows from Eqs. (201 , 202)). For what follows Hypothesis 1 will be sufficient in the form it is formulated . We have however more precise conjecture about the character of the convergence of the series ( 211). We expect the existence of the estimation

f IIg(•)II2dCo .r

q n(C)( )

for large n(C). The function q(l;) < 1 for 0 < 1; l< oo. This estimation implies the existence of a similar estimation for ITM with q = q(oo). What is the sum of series (211)? This question is very important . It is natural to suppose that according to Coleman 's equivalence Eq. (2)

n(C)

(

J IIg(-e)II2dCo = ir -)

2a2

and consequently for { = oo,

J Ilga (t)II2dcto = 2a 2 n(C)

To prove these formulae directly is an extremely difficult but tempting problem. Let us pass on to NLS. For this model we suppose the following hypothesis to be valid Hypothesis 2. In NLS model the series

J llga(V)II2dCo , J Ilfa(c ) I2dcVo n(C)

n(C)

167

Current Algebras

diverge (the convergence of the integrals f II9aII2dCo, f II faIl2 dCo follows from Eq. (203)). Asymptotically for n -+ oo the n-th term of these series approach as some constant . When the ultraviolet cutoff is introduced, Ai < A, and the series become convergent:

I J

n

r An ( -6) 112 < oo , d01 ... . . f0 0 dAn-1 II9a E J A dA1...

J

A dOn-

n

1IIfa(C)II2
(212)

Assuming this hypothesis to be valid one can prove the following statement. Lemma 2. The series (212) are characterized by the following behaviour for A --> oo:

E J ^ d01...

IA

0

dAn- 1 II9a(

V

)112

..'

(41r)2 '

Proof. Denote the sums of the series f

C)II z

f

Ad01 ...

_

^d01 ...

AdAn-1 119* (

n

n

fo

o ^dzn-1IIfa(V)II2

f

by j1(A), q2(A) respectively. According to Hypothesis 2, ij1,2 (A) < oo. Differentiate q1(A) with respect to A: d oo n+1

A

= f do1

n

, n

J

dn 1191(71 , ...7K-1, 7,c + A ,

,7n +A)II2 . For large A the following estimations (200) hold: 9a (B1, B2 + A) .., A 6abcgb(Bl)9e(B2) ,

n(B1) = 0(mod 2) ,

9a (B1, B2 + A) ... 2^ 6abc fb(B1)fe(B2) , n(B1) = 1(mod 2) .

Form Factors in Completely Integrable Models of Quantum Field Theory

168

Hence for large A the formula is valid:

dd nl ( n) =

2(2ir)2 2 (71 (A)

+ riz (n))

Similarly, dn772 ( A) = 2(21r)2 1 211i (A)7l2(A) Hence , for the function ra(n) = nl(A) + 712(A) one has the equation do i7(A ) = 2(2x)2 n2 271 (A) . The solution of this differential equation is A

It c A +2(2x)2 According to Hypothesis 2, q (A) --> oo for A -+ oo; hence c = 0, which means that for large A the following asymptotic holds : j7(A) ^ 2 21 T 2A. Hence , n;(A) = cin for A - oo. Substituting these rlt into the above equations one gets ", .v 772 (A) 771(A) (47r)2 Q.E.D. The possibility of indicating an explicit asymptotic behaviour of 711,2(A) in the framework of Hypothesis 2 is very important and, as it will be clear later, is a strong indirect argument in favour of this hypothesis. Now, assuming the validity of Hypothesis 1, 2, let us pass on to calculation of the singularities of commutators at the origin of coordinates. Theorem 1. The following commutation relations between currents on the space interval for ITM hold: [70a(x), 70(0)) = i6abcjo(0)b(x) W1(x), 71(0) = Zeabcj o(0)a(x)

Uo(x), 7i(0)] = ieabcji(x)S(x) + 4babij6'(x)ai, where

00 C dCo r (-)112 7 J II9a n(C) =O

(213)

Current Algebras

169

Proof. Look at the formula (206),

(A I J[Oi(x), 02(0))e

p(x) dxjd B )

= J {7Io1 x)o2(o )I B)- - (A 1O2 (0)O1(x)I B)+} e',c(A ) s^o -(x)dx +

f

{ 7 IO 1

x)O2(o I+ - ( A 102(0)01(x) 1 B)- } e'ic(A):p +(x)dx

(214)

and consider the first term in RHS,

J {7IO1( xO2oI_ - (1102 (0)01(x)I B )+} e',(A)xso-(x)dx S(AIA1)S(A3IA3) > A=A1uA2uA3 n(C)-0 B=B1uB2uB3 X

0(A3, B3)S(B 21B2

U B3)S(B2

U B31 B)

f

dCG_(xIC,A1,B1,A3)

(215)

,

where G- (C, A1, B1, A3) = (-1)n

( Bl)+n(B2)+n(C)[ f1

(A1 + i01 U B 2)

S(CIA3U C)f2((C U A 2)-i01B1 ) c _(ic ( C)+ic(B )+ ic(A3)

+ c(A2))-f2(A2-i0IB1U C)S(C U A31C) X f1((A 1 U C) + i0I B 2)co_ (-,(C) + c(B2) + ic (A3) + tc(A2)) (216) The principal statement of Sec. 2 is that the matrix element ( 214) vanishes if
(217)

because the first and second terms in (216) are the boundary values of a regular function in the strip -a < Imo- < 0 on the lines Imo = 0 and Imv = - a + 0, and this regular function decreases for a -^ ±oo.

170

Form Factors in Completely Integrable Models of Quantum Field Theory

The asymptotics (187) implies that fµ and f,6, do not increase faster than e"°i for o, - ^ ±oo. Hence the condition that 0_ (ic) decreases faster than an arbitrary power of ic-1 can be replaced by the following: 0_(ic) decreases as is-3 for ic -+ oo. Under this condition on Eq. (217) remains valid. The condition iO_(it) - k-3 for i -+ oo is equivalent to W(0) = (p'(0) = 0. There are no restrictions on other derivatives, hence the commutator (I U,'.-(x), j'(0)] I B) does not contain other singularities but those proportional to b and Y. We want to extract the b and 6' singularities from the commutators. To this end we need to consider a convolution of commutators with the functions which do not vanish at the point x = 0. One should be careful at this point because in the cases we shall consider later the integral

J dofl(A1+i0ICU Bz)S(CIA3U C).fz(C U A2IB1+i0) (218)

x 0- (tc(C) + ic(B2) + ic (A2) + ic(Aa)) diverges , which means that the convolution

J Ol(x)Oz(0)
00 [01

02 (0 )]l B) = ^ m

J ((Ioi(x)i)

00 n(o) -o

X (DIO2(0) IB)_ - (AIO2 (0)I D)(DIO1 (x)I B)) n(O)

x

f f 9(A - bj+l + bj)dD ,

j= 1

where D = {b1, ... , bn(D)}, 6n(D) > ... > bz > bl . In other words, we demand that the difference between two nearest rapidities does not exceed A and then take the limit A -> oo . Lemma 2 of Sec . 1 implies that D = C U A2 U B2 U A3. Let us denote the minimal and maximal rapidities in Az U Bz UA3 by fln"' and #,'n respectively . Let C = {yl) ... , yn(C)}, Di =

Current Algebras

min

171

Y, Cmax Yn (C)

max

A 40-

Y,

Cmin

Yn ( C)

Pmin Pmax Fig. 6.

7i-1 - yi, Q = n j EryEC y and fix 01 i ... , An(C)_1, then o, may vary in the range from Amin to trmax as indicated in Fig. 6.

The integral

r

J dad_ (C, AI, B1i A3)

(219)

changes under the limit sign to

om dvG_ (C,A,,B1,A3) = (J -J) A (7+ioiu2)

J

Il )9

omin

X

.S(li

I A3 U

C)f2(C'

U A3 )

B 1)0-(4C) + ic(B2) + ic(A3) + ic(A2)) , (220)'

where I1, I2 are segments parallel to the imaginary axes II = ( °min) 0min ii), I2 = ( t7max, Amax - 7ni ). Evidently the limit of the integral (220) can exist when the integral (219) diverges. It is desirable to work with such operators for which only the leading term of asymptotics contributes to (220) for a -a ±oo.

The first commutation relation we intend to obtain is

[j+a (x) , jb (0)] = 0 ,

(221)

where jf = 12 (jo ± ji ). Form factors f. , f f are written through ga as follows: f+(fll,... #2.) = M(> e,6j)ga(/31,,... ,)32.) , f b (Nl, ... ,N2n) = M(> e-1i) ga(Nl, ... , 02n)

172 Form Factors in Completely Integrable Models of Quantum Field Theory

Let