Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality

Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality

We study integrable deformations of sine-Liouville conformal field theory. Every integrable perturbation of this model is related to the series of quantum integrals of motion (hierarchy). We construct the factorized scattering matrices for different integrable perturbed conformal field theories. The...

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Автор: Fateev, V.A.
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Опубліковано: Інститут математики НАН України 2017
Назва видання:Symmetry, Integrability and Geometry: Methods and Applications
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Цитувати:Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality / V.A. Fateev // Symmetry, Integrability and Geometry: Methods and Applications. — 2017. — Т. 13. — Бібліогр.: 44 назв. — англ.

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spelling irk-123456789-1492402019-02-20T01:23:56Z Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality Fateev, V.A. We study integrable deformations of sine-Liouville conformal field theory. Every integrable perturbation of this model is related to the series of quantum integrals of motion (hierarchy). We construct the factorized scattering matrices for different integrable perturbed conformal field theories. The perturbation theory, Bethe ansatz technique, renormalization group and methods of perturbed conformal field theory are applied to show that all integrable deformations of sine-Liouville model possess non-trivial duality properties. 2017 Article Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality / V.A. Fateev // Symmetry, Integrability and Geometry: Methods and Applications. — 2017. — Т. 13. — Бібліогр.: 44 назв. — англ. 1815-0659 2010 Mathematics Subject Classification: 16T25; 17B68; 83C47 DOI:10.3842/SIGMA.2017.080 http://dspace.nbuv.gov.ua/handle/123456789/149240 en Symmetry, Integrability and Geometry: Methods and Applications Інститут математики НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description We study integrable deformations of sine-Liouville conformal field theory. Every integrable perturbation of this model is related to the series of quantum integrals of motion (hierarchy). We construct the factorized scattering matrices for different integrable perturbed conformal field theories. The perturbation theory, Bethe ansatz technique, renormalization group and methods of perturbed conformal field theory are applied to show that all integrable deformations of sine-Liouville model possess non-trivial duality properties.
format Article
author Fateev, V.A.
spellingShingle Fateev, V.A.
Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality
Symmetry, Integrability and Geometry: Methods and Applications
author_facet Fateev, V.A.
author_sort Fateev, V.A.
title Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality
title_short Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality
title_full Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality
title_fullStr Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality
title_full_unstemmed Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality
title_sort integrable deformations of sine-liouville conformal field theory and duality
publisher Інститут математики НАН України
publishDate 2017
url http://dspace.nbuv.gov.ua/handle/123456789/149240
citation_txt Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality / V.A. Fateev // Symmetry, Integrability and Geometry: Methods and Applications. — 2017. — Т. 13. — Бібліогр.: 44 назв. — англ.
series Symmetry, Integrability and Geometry: Methods and Applications
work_keys_str_mv AT fateevva integrabledeformationsofsineliouvilleconformalfieldtheoryandduality
first_indexed 2025-07-12T21:10:58Z
last_indexed 2025-07-12T21:10:58Z
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fulltext Symmetry, Integrability and Geometry: Methods and Applications SIGMA 13 (2017), 080, 22 pages Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality Vladimir A. FATEEV †‡ † Laboratoire Charles Coulomb UMR 5221 CNRS-UM2, Université de Montpellier, 34095 Montpellier, France E-mail: Vladimir.Fateev@univ-montp2.fr ‡ Landau Institute for Theoretical Physics, 142432 Chernogolovka, Russia Received April 24, 2017, in final form October 03, 2017; Published online October 13, 2017 https://doi.org/10.3842/SIGMA.2017.080 Abstract. We study integrable deformations of sine-Liouville conformal field theory. Eve- ry integrable perturbation of this model is related to the series of quantum integrals of motion (hierarchy). We construct the factorized scattering matrices for different integrable perturbed conformal field theories. The perturbation theory, Bethe ansatz technique, renor- malization group and methods of perturbed conformal field theory are applied to show that all integrable deformations of sine-Liouville model possess non-trivial duality properties. Key words: integrability; duality; Ricci flow 2010 Mathematics Subject Classification: 16T25; 17B68; 83C47 1 Introduction Duality plays an important role in the analysis of statistical, quantum field and string theory systems. Usually it maps a weak coupling region of one theory to the strong coupling region of the other and makes it possible to use perturbative, semiclassical and renormalization group methods in different regions of the coupling constant. For example, the well known duality between sine-Gordon and massive Thirring models [7, 31] together with integrability plays an important role for the justification of exact scattering matrix [39] in these theories. Another well known example of the duality in two-dimensional integrable systems is the weak-strong cou- pling flow from affine Toda theories to the same theories with dual affine Lie algebra [2, 6, 9]. The phenomenon of electric-magnetic duality in four-dimensional N = 4 supersymmetric gauge theories conjectured in [21, 32] and developed for N = 2 theories in [36] (and in many subse- quent papers) opens the possibility for the non-perturbative analysis of the spectrum and phase structure in supersymmetric gauge field theories. Recently discovered remarkable field/string duality [22, 28, 29, 38] leads to the unification of the ideas and methods for the analysis of these seemingly different quantum systems. Known for many years the phenomenon of duality in quantum field theory still looks rather mysterious and needs further analysis. This analysis essentially simplifies for two-dimensional integrable relativistic systems. These theories besides the Lagrangian formulation possess also unambiguous definition in terms of factorized scattering theory, which contains all information about off-mass-shell data of quantum theory. These data permit one to use non-perturbative methods for the calculation of observables in integrable field theories. The comparison of the observables calculated from the scattering data and from the perturbative, semiclassical or renormalization group analysis based on the Lagrangian formulation makes it possible in some This paper is a contribution to the Special Issue on Recent Advances in Quantum Integrable Systems. The full collection is available at http://www.emis.de/journals/SIGMA/RAQIS2016.html mailto:Vladimir.Fateev@univ-montp2.fr https://doi.org/10.3842/SIGMA.2017.080 http://www.emis.de/journals/SIGMA/RAQIS2016.html 2 V.A. Fateev cases to justify the existence of two different (dual) representation for the Lagrangian description of quantum theory. Two particle factorized scattering matrix is rather rigid object. It is constrained by the global symmetries, factorization equation and unitarity and crossing symmetry relations. After resolution of these equations the scattering matrix S can contain one (or more) free parameter. At some value of this parameter λ = λ0 the scattering matrix S(λ0) becomes identity matrix and possesses the regular expansion at (λ − λ0) near this point. In many cases this expansion can be associated with perturbative expansion of some Lagrangian theory with parameter b near some free point. In some cases S(λ) contains other point λ1 where S(λ1) is the identity matrix and admits the regular expansion in (λ − λ1). If this expansion can be associated with some perturbative expansion with other local Lagrangian and small coupling γ = γ(b), then two different Lagrangians describe the same theory, which possesses two different (dual) perturbative regimes. More interesting situation occurs when S(λ) has the regular expansion in (λ−λ0) which is in perfect agreement with perturbative expansion in b of some field theory with local action A(b), but at the point λ1 the S-matrix tends to some “rational” scattering matrix corresponding to the S-matrix of the nonlinear sigma model on the symmetric space. Near the point λ1 it can be considered as the deformation of the symmetric scattering. In this case it is natural to search the dual theory as sigma model with target space looking as deformed symmetric space. The metric of sigma model on the manifold is subject to very rigid conditions, namely nonlinear renormalization group (RG) equations [19]. If one has found the solution of RG equations which gives the observables in the sigma model theory, coinciding with that’s derived from the factorized S-matrix theory one can conclude that the field theory with the action A(b) is dual to the sigma model on the deformed symmetric space. The short distance pattern of such theory can be studied by RG and conformal field theory (CFT) methods. The agreement of the CFT data, derived from the action A(b) (considered as a perturbed CFT) with the data derived from RG data for sigma model gives an additional important test for the duality. The CFT data play an important role in justification of the third type of the duality. In this case one has the sigma model with singular metric. The nice property of such sigma models is the validity of RG flow from the short distances up to the long ones. The RG trajectory relates the non-rational CFT in the ultraviolet (UV) regime with the rational CFT in the infrared (IR). The field theory dual to sigma model flowing to rational CFT manifests the phenomenon of quantization of the coupling constant. The large class of two-dimensional quantum field theories can be considered as perturbed CFTs. In this paper we consider the integrable field theories which can be formulated as sine- Liouville CFT perturbed by proper fields. In Section 2 we describe sine-Liouville CFT and show the duality of this model with Witten’s black hole (cigar) CFT. We note that it gives the simple example of the field/string duality [22, 29, 28, 38]. In Section 3 we describe the W-algebra of S-L CFT and show that the enveloping algebra of this W-algebra contains three different Cartan subalgebras. These Cartan subalgebras de- termine three series of quantum integrals of motion. Each of them is defined by the integrable perturbation of the sine-Liouville CFT. The local integrals of motion are specified by their densities Ps which are local fields with the Lorentz spins s and satisfy the continuity equation ∂z̄Ps = ∂zΘs−2 with a local field Θs−2. Here {z, z̄} are the standard light cone (or complex) coordinates. The factorized scattering for all three types of integrable perturbations theories are con- structed in Section 4. The Bethe ansatz (BA) technique is applied to justify that the first two field theories have the dual representations, which are available for weak perturbative analysis in different regions of the coupling constant. The phenomenon of fermion-charged boson duality is studied. Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 3 To justify the duality of third integrable perturbation with sausage sigma model we study the RG (Ricci flow) equations for the metric of this model in Section 5. It is shown that the RG data are in agreement with the data derived by BA method from scattering theory. The test for duality of field theory with sausage sigma model, based on comparison of RG data at the finite space circle with the thermodynamic Bethe ansatz (TBA) data is done in Section 6. In Section 7 we use the same approach for the analysis of sigma model with singular metric. This solution of Ricci flow equation describes the RG trajectory from UV to IR regime. The dual field theory action is conjectured. In Section 8 we describe the massless scattering theory for the RG flow described by singular sigma model and TBA equations following from this scattering theory. The TBA equations, RG data and the methods of perturbed CFTs are used to conjecture the duality and to prove the existence of RG flow from non-rational CFT in UV regime to rational in IR regime. The part of the results of this paper presented in Sections 2, 4, 5 and 6 were derived and published in collaboration with A. Zamolodchikov, Al. Zamolodchikov and E. Onofri. Some of results presented in Sections 3, 7 and 8 are new and where reported in the conference dedicated to the memory of Vadim Knizhnik (IHES, October 2013). The author dedicates this paper to memory of this brilliant scientist. 2 Sine-Liouville conformal field theory – Witten’s black hole duality Witten’s two-dimensional black hole model [37] is described by the sigma model with action which corresponds to the metric ds2 = k ( dr2 + ( tanh2 r ) dθ2 ) . (2.1) This model with the dilaton field D = log ( cosh2 r ) is described by the CFT with the central charge c = 2 + 6 k−2 , which is also known as the coset SL(2,R)/U(1)-parafermionic theory [10]. The spectrum of this CFT is well known and has the form ∆P,m,n = − 1 k − 2 + P 2 + 1 4k (m± nk)2, (2.2) where P is continuous variable and m, n the are integers respectively. The numbers m and n are called the momentum and the winding numbers. If θ is 2π periodic coordinate the metric (2.1) describes a manifold with a shape of semi-infinite cigar Figure 1. Euclidean 2d black hole “cigar”. One can easily see from this picture that the momentum number m is conserved and the winding number n of the string moving on the cigar can change. This CFT has a T -dual theory with the metric and dilaton, which can be derived from (2.1) by the transformation r → r + iπ2 ds2 = k ( dr2 + ( coth2 r ) dθ̂2 ) . The spectrum of the T -dual CFT has the same form (2.2) with the substitution m ↔ n, i.e., the momentum number transforms to the winding one. Corresponding manifold has a form of the trumpet [10] 4 V.A. Fateev Figure 2. “Trumpet” embedded in 3d Euclidean space. Now one can see that the winding number on this manifold is conserved and the momentum number can change due to the singularity of this manifold. Sine-Liouville CFT is described by the action A = ∫ d2x ( (∂µϕ)2 + (∂µφ)2 16π + 2µebϕ cos(aφ) ) , where we accept the normalization of the fields ϕ, φ 〈ϕ(z, z̄)ϕ(0)〉 = −2 log(zz̄) + · · · , 〈φ(z, z̄)φ(0)〉 = −2 log(zz̄) + · · · , and the parameters a and b satisfy the relation a2 − b2 = 1 2 . The stress energy tensor for this CFT is T = −1 4 (∂zϕ)2 − 1 4 (∂zφ)2 + 1 4b ∂2 zϕ. If we parametrize: a2 = k 4 , b2 = k−2 4 the central charge of S-L model will coincide with the central charge of SL(2,R)/U(1) coset CFT c = 2 + 3 2b2 = 2 + 6 k − 2 . The coset SL(2,R)/U(1) CFT is a parafermionic CFT. The SL(2,R) parafermions (non-compact parafermions) (Ψ,Ψ∗) ≡ (Ψ(+),Ψ(−)) can be represented [33] by the chiral parts φ(z) and ϕ(z) of local fields φ(z, z̄), ϕ(z, z̄): φ(z, z̄) = φ(z) + φ̄(z̄), Ψ(±)(u) = i 2a (ia∂uφ± b∂uϕ)e± i 2a φ(u). These currents commute with the fields V±(z) = ebϕ(z)±iaφ(z) which form the potential of sine- Liouville (S-L) CFT, i.e.,∮ u dzΨ(±)(u)V+(z) = ∮ u dzΨ(±)(u)V−(z) = 0. It means that the W-algebra generated by the holomorphic SL(2,R)/U(1) parafermionic cur- rents Ψ(±)(u) as the set of local currents appearing in their operator product expansion coincides with the W-algebra of S-L model Ψ(+)(u)Ψ(−)(0) = 1 u2+2/k { I + b2 a2 u2W2(u) + u3 i 2a3 W3(u) + · · · } , (2.3) Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 5 where W2 = T (z) and all other currents Wi can be derived from OPE (2.3). For example W3 = ( 6b2 + 1 ) 6 (∂φ)3 + b2∂φ(∂ϕ)2 + 2b3 ( ∂φ∂2ϕ− ∂ϕ∂2φ ) − b∂ϕ∂2φ+ a2/3∂3φ. All currents Wi commute with the fields V±(v) and form the symmetry algebra of sine-Liouville CFT. The primary fields of S-L model are the local fields (∂µφ̂ = εµν∂vφ) Φα,n,m = exp ( αϕ+ ianφ+ i 1 4a mφ̂ ) . (2.4) The right and left dimensions of these fields are ∆ (±) α,n,m = α ( 1 2b −α ) + 1 4k (m±nk)2 and coincide with the spectrum of the primary fields in SL(2,R)/U(1) CFT if we put α− 1 4b = iP . Two point functions z 2∆ (+) α,n,m 12 z̄ 2∆ (−) α,n,m 12 〈Φα,n,m,Φα,−n,−m〉 (reflection amplitudes) of these primary fields in S-L theory (α′ = α− 1 4b) can be easily calculated and are Rα,n,m = ( πµ 4b2 )−2α′/b Γ(1 + 4bα′)Γ(1 + α′/b) Γ(1− 4bα′)Γ(1− α′/b) × Γ ( 1 2 − 2bα′ + |m|+nk 2 ) Γ ( 1 2 − 2bα′ + |m|−nk 2 ) Γ ( 1 2 + 2bα′ + |m|+nk 2 ) Γ ( 1 2 + 2bα′ + |m|−nk 2 ) , k = 4a2. (2.5) These functions coincide with the two point functions in SL(2,R)/U(1) CFT. The same is valid for the three point functions. As these functions together with the symmetry algebra W determine completely the theory, we can conclude (as it was done in the unpublished paper by A. Zamolodchikov, Al. Zamolodchikov and author) that S-L theory is dual to SL(2,R)/U(1) CFT. 3 Integrals of motion and integrable perturbations of sine-Liouville CFT The starting point for the analysis of the integrable perturbations of CFT with W symmetry is the description of different Cartan subalgebras in the enveloping algebra of W. Every such Cartan subalgebra is classified by integrable perturbation and generates the hierarchy of integrals of motions in the perturbed CFT. These integrals can be represented by their densities Ps which are defined up to the total derivative ∂O. If we want that our hierarchy started with density of spin three the density should coincide up to derivative with W3. It is convenient to introduce the notation: T1 = −1 4(∂zϕ)2− 1 2 ( 2b+ 1 2b ) ∂2 zϕ which is formally the stress-energy tensor of Liouville CFT with the coupling constant −2b. Then the density P (1) 3 is P (1) 3 = ( 6b2 + 1 ) 6 (∂φ)3 − 4b2∂φT1. The density of the next integral in this hierarchy has spin 4 and equals to P (1) 4 = ( 5b2 + 1 4 ) (∂φ)4 + ( 8b4 + 8b2 + 1 2 ) (∂2φ)2 + 4b2:T 2 1 : + 6b2T1(∂φ)2, here : · : denotes the regular part of the operator product. The densities P (1) s have all integer spins and transform under ∂φ → −∂φ as P (1) s → (−)sP (1) s . The integrals Is of this hierarchy correspond to perturbation of S-L model by the exponential term µ1e −2bϕ. 6 V.A. Fateev The second hierarchy is generated by the densities P (2) s with even s. The first non-trivial P (2) 4 is P (2) 4 = P (1) 4 + 9b2 2b2 − 1 2b2 + 3 :T 2:. The densities P (2) s are invariant under the transformation ∂φ → −∂φ. They correspond to the S-L CFT perturbed by the operator µ2e −bϕ. The third hierarchy of densities P (3) s with even spins s is invariant under ∂φ → −∂φ and ∂ϕ→ −∂ϕ. The first non-trivial P (3) 4 is P (3) 4 = P (1) 4 + 12b2(4b2 + 1):T 2:. It corresponds to S-L model perturbed by fields µe−bϕ cos aφ, and µe−bϕ cos aφ̂. 4 Scattering theory and dual representations 1. Integrable perturbation µ1e −2bϕ (f irst hierarchy). With the first integrable pertur- bation µ1e −2bϕ we have L1 = (∂µϕ)2 + (∂µφ)2 16π + 2µebϕ cos(aφ) + µ1e −2bϕ. (4.1) For small b one can use the two-dimensional fermion-boson Coleman–Mandelstam correspon- dence [7, 31], between fields φ and ψ to rewrite L1 in the form convenient for the perturbation theory (PT) in b: L1 = 1 16π ( (∂µϕ)2 + 2M2 b2 cosh 2bϕ+ 2Mψψebϕ ) + LTM, (4.2) where the term M2 b2 e2bϕ plays the role of the usual counterterm canceling the divergencies coming from the fermion loops and LTM is the Lagrangian of massless Thirring model LTM = 1 8π ( iψγµ∂µψ − b2 2a2 ( ψγµψ )2) . (4.3) In the PT the spectrum of the theory has two charged particles ψ, ψ+ with masses M1 and one unstable for b2 > 0 bosonic neutral particle with mass 2M . The integral P (1) 3 forbids the reflection amplitude R+−(θ) (here θ is the relative rapidity of colliding particles) in ψψ+ scat- tering. It means that the scattering is diagonal and is a pure phase. Namely the S-matrix S(1) is S++(θ) = S−−(θ) = S+−(iπ − θ) = − cosh ( θ 2 + i∆ 2 ) cosh ( θ 2 − i ∆ 2 ) . The PT gives ∆ = π b 2 a2 + O ( b6 ) . To derive exact relation between b and ∆ we can use BA approach. Our theory has U(1) symmetry generated by the charge Q = 1 8π ∫ ψψ+dx1. (4.4) 1The exact relation between the parameter µ1 and the physical mass M in the action (4.1) can be derived by the BA method [13, 40] and has the form µ1 = − Γ(−b2) πΓ(1 + b2) ( M 4 √ π Γ ( 1 2(1 + b2) ) Γ ( 1 + b2 2(1 + b2) ))2(1+b2) . Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 7 We add to our Hamiltonian the term −AQ where A is an external field (chemical potential) and calculate the asymptotic of the specific ground state energy E(A) (GSE) in the limit A M → ∞. In this limit we can neglect all terms that contain parameter M in the Lagrangian and derive the well known expression for the massless Thirring model E(A→∞) = −a 2A2 π = − ( 1 + 2b2 ) A2 2π . The same value can be calculated from the Bethe ansatz (BA) equations in the external field. Due to the additional term AQ in the Hamiltonian every positive charged particle acquires the additional energy A. For A > M the ground state contains a sea of these particles ψ(θ) which fill all positive states inside some interval −B < θ < B. The distribution ε(θ) of these particles is determined by their scattering amplitude S++(θ). The GSE in the field A has the form E(A)− E0 = −M 2π ∫ cosh(θ)ε(θ)dθ, where ε(θ) satisfies, inside the interval −B < θ < B, the BA equation∫ B −B K̂(1)(θ − θ′)ε(θ′)dθ′ = A−M cosh θ (4.5) and B is determined by the boundary conditions ε(±B) = 0. The kernel K̂(1)(θ) is related with the ψψ scattering phase as K̂(1)(θ) = δ(θ)− 1 2πi d dθ log(S++(θ)). (4.6) It has the Fourier transform K(1)(ω) = 2 sinh[(π −∆)ω/2] cosh[(π + ∆)ω/2] sinh(πω) . (4.7) The asymptotic E(A → ∞) can be expressed through the kernel K(ω) at ω = 0 [17]. For the kernel (4.7) one has E(A→∞) = − A2 2πK(0) = − A2 2(π −∆) , or ∆ = πb2 a2 = 2πb2 1+2b2 . At b→∞, ∆→ π. We introduce parameter 4γ2 = 1 b2 . Then ∆ = π− 2γ2π 1+2γ2 and S++(θ) = S−−(θ) = S+−(iπ − θ) = sinh ( θ 2 − iγ2π 1+2γ2 ) sinh ( θ 2 + iγ2π 1+2γ2 ) . In the limit b → ∞, γ → 0 we have the free theory, but contrary to b � 1 case S-matrix tends to 1 but not to −1. Such behavior is characteristic for bosonic particles. In this limit K(1)(ω)→ (π−∆)ω tanhπω . The BA equations with this kernel can be solved and E(A)− E(0) = −(A−M)2 2(π −∆) +O(1). (4.8) The GSE (4.8) has a threshold behavior (A → M) unusual for fermionic particles, which have there the singularity (A −M)3/2. The quadratic behavior (4.8) is characteristic behavior for weakly coupled bosonic particles, it reflects the instability of free bosons under the introduction 8 V.A. Fateev of external field. The S-matrix in this limit coincides with S-matrix of complex sinh-Gordon model with L̂1 = 1 4π ( ∂µχ∂µχ ∗ 1 + γ2χχ∗ +M2χχ∗ ) , (4.9) where χ = χ1 + iχ2 is a complex scalar field. Complex sinh-Gordon model is integrable clas- sically [27, 35]. The quantum integrability and renormalizability of this theory was studied in [5, 8]. For b � 1, γ � 1 the theory is described by weakly coupled charged bosons χ, χ∗ with masses M . The external field A can be introduced by ∂0 → ∂0 + iA. It is easy to check that E(A) in this case can be derived by minimization of Euclidean action for constant χ E(A) = min χ [ 1 4π ( − A2χχ∗ 1 + γ2χχ∗ +M2χχ∗ )] . The duality between the QFTs (4.2) and (4.9) gives us an example of the fermion-boson duality, when the charged particles being the fermions in weak coupling regime become the bosons in the strong coupling one. 2. Integrable perturbation µ2e −bϕ (second hierarchy). The Lagrangian L2 in the form convenient for PT at small b is L2 = 1 16π (∂µϕ)2 + 2Mψψebϕ + M2 b2 ( e2bϕ + 2e−bϕ ) + LTM, (4.10) where LTM is the Lagrangian for the massless Thirring model (4.3). In the PT the spectrum consists from two charged particles ψ, ψ+ with masses M and one neutral particle (their bound state) with mass √ 3M . In this case we do not have conserved currents with odd spins and in PT amplitude R+− 6= 0. The U(1) symmetric solution of Yang–Baxter equation up to CDD factors coincides with the S-matrix of the sine-Gordon model SSG: S++ ++(θ) = S+− +−(iπ − θ) = −eiδλ(θ), S+− −+(θ) = −i sinπλ sinhλ(iπ − θ) eiδλ(θ), (4.11) where δλ = ∫ ∞ 0 dω sin(ωθ) sinh[ωπ(1− λ)/2λ] ω cosh(ωπ/2) sinh[ωπ(1/2λ)] , λ = 1 β2 SG −1, and βSG is the coupling constant in sine-Gordon model. S-matrix (4.11) corresponds to cUV = 1. We expect that for our QFT cUV = 2. It can be achieved by addition of one CDD factor. At b → 0 the S-matrix for QFT (4.10) is −I + O(b2). It means that at b → 0 the CDD factor should cancel sine-Gordon S-matrix, i.e., at b = 0 S-matrix SSG should be diagonal at λ(0) and contain only one factor. It happens if λ(0) = 3. For this λ the S-matrix (4.11) has the poles at θ1 = i2π 3 and θ1 = iπ 3 . The first pole will be canceled by CDD factor and the second gives the bound state with the mass M1 = 2M sin π 3 = √ 3M , what agrees with the PT. It means that S(2)(θ) = −sinh(θ)− i sin(π/λ) sinh(θ) + i sin(π/λ) SSG(λ, θ). To find the function λ(b) we introduce the field A coupled with the charge (4.4). At A/M →∞ we have the same result that for QFT (4.2) E(A)→ −a2A2 π . The kernel K̂(2)(θ) is now expressed throw 1 2π d dθδ ++(θ), where δ++(θ) is the phase of scattering of particles ψψ : δ++(θ) = δλ + 1 i log sinh(θ)−i sin(π/λ) sinh(θ)+i sin(π/λ) . The Fourier transform of this kernel is K(2)(ω) = sinh ( πω 2 ( λ−1 λ )) cosh ( 3πω 2λ ) sinh ( πω λ ) cosh ( πω 2 ) Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 9 and E(A→∞) = − A2 2πK(2)(0) = − A2 π(λ− 1) . Comparing two expressions we derive λ = 3+2b2 1+2b2 . At b → ∞, λ → 1 and we again have S → I + O(γ2). The mass of the neutral particle M1 = 2M sin ( π λ ) and at λ = 2 or 2b2 = 1 it disappears from the spectrum and we have only two charged particles. At b2 � 1, γ2 = 1 4b2 the kernel K(2) = 2γ2 πω cosh(3πω/2) cosh(πω/2) sinh(πω) and E(A) can be calculated. The result can be written in the parametric form [14] E(A)− E(0) = − A2 4πγ2 ( 1− 3X +X2 + X3 (1−X) ) , ( M A )2 = 4X3 (1−X) . It is easy to check that E(A) coincides with the minimum of the Euclidean action (after ∂0 → ∂0 + iA) for the QFT with Lagrangian L̂2 = 1 4π ( ∂µχ∂µχ ∗ 1 + γ2χχ∗ +M2χχ∗ ( 1 + γ2χχ∗ )) . The perturbative expansion in γ2 for the S-matrix confirms this suggestion. Here we see not only the phenomenon of the Dirac fermion-charged boson duality but also that due to the non- trivial kinetic term, the interaction, which looks as repulsive potential becomes attractive for finite γ and produce the bound state for γ2 > 1 2 . 3. Integrable perturbation µe−bϕ cos(aφ) dual to the sausage model (third hier- archy). The Lagrangian of the perturbed S-L CFT now is L3 = 1 16π ( (∂µϕ)2 + (∂µφ)2 ) + 4µ cosh(bϕ) cos(aφ). (4.12) The Lagrangian L3 in the form convenient for PT at small b is L3 = 1 16π ( (∂µϕ)2 + 2Mψψ cosh(bϕ) + M2 b2 sinh2(bϕ) ) + LTM, (4.13) where the term with sinh2 bϕ plays the role of the counterterm and LTM is given by (4.3). In the PT the spectrum consists from two charged (ψ,ψ+) or (+,−) and one neutral particle (ϕ) or (0) with the same mass M . The S-matrix S(3)(θ) for such set of particles is known [17, 41] and up to C, P, T Sijkl(θ) = S ı̄j̄ k̄l̄ (θ) = Sjilk(θ) = Sklij (θ) and crossing Sijkl(θ) = Sjk̄l̄ı (iπ − θ) symmetries has the following independent amplitudes Sijkl(θ), where i, j, k, l = +, 0,−, and i+j = k + l, j̄ = −j, S++ ++(θ) = sinhλ(θ − iπ) sinhλ(θ + iπ) , S0+ +0 = −iS++ ++(θ) sin 2πλ sinhλ(θ − 2iπ) , S+0 +0 = S++ ++(θ) sinhλθ sinhλ(θ − 2iπ) , S+− −+ = − sin 2πλ sinπλ sinhλ(θ − 2iπ) , S00 00 = S+0 +0 + S+− −+ . (4.14) 10 V.A. Fateev In the perturbation theory we derive λ = 1 2−b 2+O(b4). To find exact function λ(b) we introduce the external field A coupled with the charge (4.4). Again we have that E(A → ∞) → −a2A2 π . The kernel of BA equations (4.5), (4.6) is now K̂(3)(θ) = δ(θ)− 1 2πi d dθ log(S++ ++(θ)) = δ(θ)− λ π sin 2πλ cosh 2λθ − cos 2πλ . It has the Fourier transform K(3)(ω) = 2 sinh [ πω 2 ] cosh [πω(1−λ) 2λ ] sinh [ πω 2λ ] , (4.15) and E(A→∞) = − A2 2πK(3)(0) = − A2 4πλ , or λ = 1 4a2 = 1 2(1+2b2) = 1 k . At b → ∞, λ → 0 and our S-matrix coincides with the S-matrix of the O(3) sigma model. For finite b� 1 it is natural to search the dual representation of the QFT (4.12), (4.13) as U(1) symmetric deformation of this sigma model. As the deformed O(3) sigma model should be compared with QFT (4.12), (4.13), we consider the BA equations here more attentively. We should show that observables in this QFT calculated from the S-matrix data in the UV region coincide with the same observables in the sigma-model analysis. As the observables calculated from S-matrix data we consider here the GSE in the external field E(A) and E0(R) the GSE of the model at the finite size circle of length 2πR (see later). To start, we consider the function E(A). The BA equations can be solved by generalized Winner–Hopf technique [20], which permits to develop the large ( A M ) expansion. This expansion of E(A) for kernel (4.15) runs in two types of exponents: instanton exponents ( M A )2q and perturbative exponents ( M A ) 2λ 1−λ , namely E(A) = − A2 4πλ ∞∑ q=0 ( M A )2q f (q) ( A M ) , (4.16) where the functions f (q) ( A M ) , are the regular series in ( M A ) 2λ 1−λ . For example, f (0) ( A M ) = ( 1− 4 ( 1− λ 1− 2λ )2 Γ ( −λ 2−2λ ) Γ ( 1 2−2λ ) Γ ( λ 2−2λ ) Γ ( −1 2−2λ ) (2λM A ) 2λ 1−λ + · · · ) . The instanton exponents in the expansion (4.16) appear due to the instanton contributions and the perturbative exponents as the sum of PT around the q-instanton solution. The instanton exponents do not depend on coupling constant b. We note that instantons appear in all sigma models with the compact two-dimensional target space. For b� 1, λ� 1 and the main contribution to E(A) comes from f (0) ( A M ) . The BA equations simplify drastically in the scaling limit λ→ 0, log ( A M ) →∞ with λ log ( A M ) fixed. Corrections to the scaling behavior also can be developed. Here we give the scaling limit of E(A) together with the leading (“two-loop”) correction [17] E(A) = − A2 4πλ 1− q 1 + q ( 1 + 4λ q 1− q2 log ( 1− q 2λ ) +O ( λ2 log2 λ )) , (4.17) where q = ( Me3/2 8A ) 2λ 1−λ . In the limit λ→ 0 we recover the result of [23] for O(3) SM. Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 11 5 Sigma models, Ricci f low and sausage sigma model The nonlinear sigma models (SM) in two-dimensional space-time are widely used in QFT as well as in relation with string theory. They are described by the action A[G] = 1 4π ∫ Gij(X)∂µX i∂µX jd2x+ · · · , (5.1) where Xi are coordinates in d-dimensional manifold called target space and symmetric mat- rix Gij(X) is the corresponding metric. The standard approach to two-dimensional SM is the perturbation theory. If the curvature is small one can use the following renormalization group (RG)-evolution equation [19]. Let t be the RG time (the logarithm of the scale) t→ −∞ in UV limit and t→∞ in IR. Then the one loop RG evolution equation is d dt Gij = −Rij +O ( R2 ) , (5.2) where Rij is the Ricci tensor of G. The analysis of this equation shows [34] that in general the nonlinear evolution equation is unstable in the sense that even if one starts from manifold of small curvature everywhere at some scale t∗, under evolution in both directions t → ±∞ the metric G(t) develops at least some regions where its curvature grows and (5.2) is no more applicable. If it happens in the UV direction t → −∞ the action (5.1) does not defines any local QFT. However, special solutions exist where UV direction is stable and curvature remains small up to t→ −∞, permitting one to define the local QFT (at least perturbatively). For example, if we have homogeneous symmetric space, its metric grows in the UV and curvature monotonously decreases and we are dealing with an UV asymptotically free QFT unambiguously defined by the action (5.1). Very interesting class of the solutions of Ricci flow equation form the solutions related with deformed symmetric spaces. The simple example of such solution (deformed sphere S2 or sausage) is considered later. The asymptotic of the solutions of Ricci flow equations at t → −∞ correspond to the fixed points of Ricci flow. They are more symmetric and subject to methods of CFT. To study the large distance physics one should find a suitable approach. The quantum integrability is one of the most successful lines in studying non-critical SMs. The quantum integrability and global symmetries of the metric are manifested in the factorized scattering theory (FST) of corresponding excitations. The FST is rather rigid and its internal restriction does not permit a wide variety of consistent constructions. The FST contains all the information about background integrable QFT. The methods of integrable QFTs allows one to compute some off-mass-shell observables on the base of FST. In the UV region these observables should be compared with that’s following from SM (5.1). If they match non-trivially in the UV region it is naturally to suggest the chosen FST as the scattering theory of integrable SM. Moreover, one can use the FST as a non-perturbative definition of the SM. At d = 2 the Ricci flow equation (5.2) is much simplified. There one has Rij = 1 2RGij , where R is the scalar curvature. Then one can always choose the conformal coordinates such that Gij = eΦδij and R = −e−Φ∂Xi∂XiΦ. The equation (5.2) now reads − d dt Φ = 1 2 R+ · · · or d dt Φ = e−Φ∂Xi∂XiΦ + · · · , the two loop correction to the first of these equations is 1 4R 2 [19]. Our SM is U(1) or axially symmetric, so in conformal coordinates X, Y we choose 0 ≤ X < 2π as angular coordinate and Φ(Y ) independent on X. Then one loop equation looks as nonlinear 12 V.A. Fateev Figure 3. RG evolution of sausage. heat equation d dt Φ(Y ) = e−Φ∂2 Y Φ(Y ). The solution of this equation is [17] eΦ = sinh 2ν(t0 − t) ν(cosh 2ν(t0 − t) + cosh 2Y ) , where ν is the real parameter. It corresponds to the action ASSM = 1 4π ∫ ((∂µX)2 + (∂µY )2) sinh 2ν(t0 − t) ν(cosh 2ν(t0 − t) + cosh 2Y ) d2x. (5.3) This manifold for u = ν(t0 − t) � 1 looks like a sphere and at u � 1 we see a long sausage of length L ' √ 2ν(t0 − t), and in the middle it tends to the cylinder with radius √ 1/ν. For this reason we call this QFT as sausage sigma model (SSM). For u = ν(t0− t)� 1 the sausage looks as two long cigars (2.1) glued together. In particular, it means that in the UV region u� 1 one can use the black hole (with k = 1 ν ) or S-L CFT data for analysis of SSM. The SSM possesses the instantons and one can add to the action (5.3) topological term iθTT where θT is a topological angle. The instantons play important role at large distances and for θT = π this theory flow from the CFT with cUV = 2 to the CFT with cIR = 1. The full analysis of this theory was done in [17]. Here we will be interested in the UV behavior, which does not depend on θT . One can compare the GSE in the external field A derived from FST data and the same value derived from SSM (5.3). The field A introduces the scale (t0 − t) = log A M . The introduction of the field A amounts the substitution ∂0X → (∂0 + iA)X in the action (5.3). The GSE derived from the action of SSM corresponds to the minimum of Euclidean action. This minimum is achieved at Y = 0. The one loop GSE E(A) then is E(A) = − 1 4πν A2(tanh(u) +O(ν log ν)), u = ν log ( A M ) . (5.4) Comparing GSEs (4.17) and (5.4) we derive that they coincide in the scaling (one-loop) appro- ximation and that ν = λ = 1 k . It is worth mentioning that the SSM action (5.3) admits also a simple parametrization in terms of unit-vector nj(x) on S2 in which one can easily see SSM as the deformation of O(3)- sigma model ASSM = 1 4πg(t) ∫ 3∑ j=1 (∂µnj) 2 1− ν2 2g2(t) n2 3 d2x, (5.5) where g(t) = ν cot(ν(t0 − t)). Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 13 6 Sausage at the circle In this section we consider SM at the circle of length R. It introduces the scale (t0 − t) = log ( 1 RM ) . In the UV scaling regime: − log(RM) → ∞, ν → 0 such that u = −ν log(RM) is finite, our one-loop approximation is exact up to O(ν log ν). In this approximation we can use minisuperspace approach to calculate the UV corrections to GSE E0(R), effective central charge E0(R) = − π 6Rc(R) and to the energies Ei(R) of exited states. It was in shown in [16, 17] that these values can be expressed throw the eigenvalues of the covariant operator ĥ ĥ = −∇2 t + 1 4 Rt, ĥΨi = ei(R) 6 Ψi, (6.1) where ∇2 t is the Laplace operator and Rt is the scalar curvature in the SSM metric renormalized at the scale R. Then with the accuracy ν log ν c(R) = 2− e0(R), Ei(R) = E0(R) + π(ei − e0) R . (6.2) Operator ĥ is self-adjoint with respect to the scalar product with the SSM metric (Ψ1,Ψ2) = ∫ Ψ∗1Ψ2e Φ(y)dxdy, where coordinates x, y can be considered as the zero modes of the fields X, Y . It is easy to see that the operator ĥ/ν 1 ν ĥΨ = −e Φ(y) ν ( 1 2 d2 dy2 + 1 8 Φ′′(y) ) Ψ depends only on the scaling variable u = −ν log(RM). It means that the eigenvalues ei(R) scale as νei(u). We can search for the solution Ψ = eixmΨm. After the substitution ey−u = cn(z|s) sn(z|s) , ψm = √ sn(z|s) cn(z|s) dn(z|s) Ψm with modulus of the elliptic Jacobi function s2 = 1 − e−4u the equation can be written in the Lamé form( − d2 dz2 − cn2(2z|s) sn2(2z|s) + m2 dn2(z|s) sn2(z|s) cn2(z|s) ) ψm = κm,js 2 6 ψm, (6.3) where em,j(R) = νκm,j(u) and the boundary conditions for the solutions are ψm ∼ zm+ 1 2 at z → 0, ψm ∼ (K − z)m+ 1 2 at z → K, where K(s2) is a real period of Jacobi functions. For small u, s2 ' 4u, K ' π 2 , the equation (6.3) can be easily solved ψm = (sin 2z)m+1/2Pj(cos 2z), where Pj are Legendre polynomials. We derive κm,j 6 ' j(j+1)+1/2 u , j ≥ m and e0(R) = νκm,0 = 3 log(1/RM) . This asymptotic is universal for all spheres Sd with d > 1 c(R) = d− 3 2 d/ log(1/RM) +O ( log(log(1/RM))/ log2(1/RM) ) . 14 V.A. Fateev We consider now another limit u� 1, s2 → 1, K ' 2u+ log 4. In this limit the potential V (z) in the Lamé equation with exponential accuracy looks as Vl(z) = − 1 sinh2 2z +m2 coth2 z, 0 < z � K, Vr(z1) = − 1 sinh2 2z1 +m2 coth2 z1, 0 < z1 = K − z � K. We parametrize κm,n 6 = m2 +4p2. Then in the middle one can neglect the potential term and ψm is the plane wave solution. At the left and right ends z ∼ 0, z ∼ K the equation can be solved exactly in terms of the hypergeometric functions F (A,B,C, z) ψ(l) m = Nl(p,m)(tanh z)m+ 1 2 (cosh z)2ipF ( A,A,m+ 1, tanh2 z ) , ψ(r) m = ψ(l) m (z1), where A = m+ 1− 2ip 2 . (6.4) The constant Nl(p,m) = Nr(p,m) is chosen from the condition ψ(l) m ' e2ipz + R (cl) l (p,m)e−2ipz, z � 1, ψ(r) m ' e2ipz1 + R(cl) r (p,m)e−2ipz1 . The corresponding solutions (6.4) are specified by the reflection amplitudes R (cl) l = R(cl) r = Γ(1 + 4ip)Γ2 ( 1 2 − 2ip+ |m| 2 ) Γ(1− 4ip)Γ2 ( 1 2 + 2ip+ |m| 2 ) . (6.5) These amplitudes coincide with the semiclassical limit b � 1, bα′ = ip, of CFT reflection amplitudes (2.5) with n = 0. (For n 6= 0 the energy levels are very large and our minisuperspace approach does not work.) Matching the solutions in different domains we derive 1 6 κm,j = m2 + π2(j + 1)2 4(u+ rm)2 +O ( u−5 ) , rm = ψ(1)− ψ ( m+ 1 2 ) , ψ(x) = Γ′(x) Γ(x) . (6.6) The UV asymptotics with the accuracy O ( M2R2 logMR ) can be derived from exact CFT reflection amplitudes with n = 0. The potential terms in L3 are 2µebϕ cos aφ, and 2µe−bϕ cos aφ. Both of them correspond to S-L CFT and have the same “quantum” reflection amplitudes (2.5). To write the equation for UV asymptotics of em,n(R) [44] we should make the substitution µ→ µ( R2π )2−2∆Pot and take the exact relation between µ and M . In our case ∆Pot = a2− b2 = 1 2 and exact relation between µ and M can be derived by BA method and is µ = M 2π . The equation for the levels is R (q) l R (q) r = 1. Namely, em,j(R) = 6 ( m2 k + 4P 2 m,j ) , where Pm,j are the solutions to the equation: log R (q) l R (q) r = 2iπ(j + 1) with R (q) l = R (q) r = R(q), R(q) = ( MR 16πb2 )−2iP/b Γ(1 + 4biP )Γ(1 + iP/b)Γ2 ( 1 2 − 2biP + |m| 2 ) Γ(1− 4biP )Γ(1− iP/b)Γ2 ( 1 2 + 2biP + |m| 2 ) . It is easy to check that in the scaling limit the UV asymptotics coincide with that derived by minisuperspace approach. The two loop correction to (6.6) can be easily calculated for u � 1 using R(q). It is νem,j 6 = m2 + π2(j + 1)2 4(u+ rm)2 ( 1 + ν 2 log ( ν 4π ) + ψ(1) (u+ rm) +O ( ν2 log2 ν )) . Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 15 Figure 4. Incidence diagram of TBA systems and source term for SSM. The effective central charge can be calculated with arbitrary accuracy from S-matrix data (TBA equations). The TBA equations for λ = ν = 1 k = 1 N form the system of N + 1 coupled nonlinear equations for N + 1 functions εa(β)2: Rρa(β) = εa(β) + 1 2π ∫ N∑ b=0 lab cosh(β − β′) log [ 1 + e−εb(β ′) ] dβ′, (6.7) E0(R) = − 1 2π ∫ N∑ b=0 ρb(β) log [ 1 + e−εb(β) ] dβ, where lab is the incidence matrix of the affine DN Dynkin diagram and ρa = Mδa0 coshβ for SSM at θT = 0 and ρa = Mδa0 2 eβ + Mδa1 2 e−β for SSM with topological term at θT = π. The TBA calculations reproduce with great accuracy the function e0(R) and scaling function κm,n(u). The comparison of numerically computed from equation (6.3) function κ0(u) and function 1 N e0(R) derived from TBA equations is represented in [17]. The excellent agreement of UV behavior of observables derived from FST data (4.14) for QFT (4.13) with that’s derived from the Ricci flow data for SSM (5.3) give us a reason to conjecture that these theories coincide and are dual. 7 Sigma model with singular metric and RG flow to rational CFT In the previous sections we discussed the SMs with compact target space. One can easily derive from the Ricci flow equation (5.2) that at d = 2 the volume of this manifold Ω = ∫ √ Gd2X = −2(t− t0) (7.1) grows linearly for t→ −∞. Contrary the “forward” RG evolution always ends at some point t0 where manifold shrinks to a point and curvature becomes infinite. It means that the only possibility to have non-trivial RG evolution in the range −∞ < (t − t0) < ∞ is to work with metric where integral (7.1) does no exist. It happens for the non-compact manifolds with singular metric. Here we consider this interesting possibility. The action of the sausage model (5.3) admits the analytic continuation Y → Y + iπ 4 , u → u+ iπ 4 , AMSM = 1 4π ∫ ((∂µX)2 + (∂µY )2) cosh 2u ν(sinh 2u+ sinh 2Y ) d2x. (7.2) 2For arbitrary λ < 1 2 the calculation of the GSE and the energies of excited states can be also derived from the nonlinear integral equations (see [1, 4] for details). 16 V.A. Fateev -20 -10 0 10 20 30 -2 -1 0 1 2 Figure 5. Ricci flow from the bell in IR to hybrid of cigar and trumpet in UV. This metric has singularity at Y = −u, i.e., coordinate Y in target space should be considered in the region Y > −u. The metric is singular but all geodesic distances are finite and we can apply to the analysis of this “massless” sigma model (MSM) the minisuperspace approach. The part of corresponding manifold which can be embedded to Euclidean space looks as a bell for large negative u (IR regime) and as a surface surgery of cigar with trumpet for u� 1 (UV regime). The metric of the bell is ds2 = k ( dr2 + ( tan2 r ) dθ2 ) , where k = 1 ν . It was shown in [25] that the action with this metric for integer k = N descri- bes ZN parafermionic CFT [42]. The analysis of the CFT with this action was done in [30]. There was shown that the theory is consistent only for integer k = N and the U(1) symmetry of action is broken up to group ZN . It means that in quantum case the surgery is possible only for ν = 1 N . The MSS equations with metric (7.2) have the form (6.1), (6.2). After the substitution Ψ = eixmΨm, ey−u = dn(z|s) k sn(z|s) , ψm = √ sn(z|s) dn(z|s) cn(z|s) Ψm, where s2 = 1 1+e−4u , it has again the Lamé form( − d2 dz2 − dn2(2z|s) sn2(2z|s) + m2 cn2(z|s) sn2(z|s) dn2(z|s) ) ψm,j = κ′m,j 6 ψm,j , (7.3) here em,j(R) = νκ′m,j(u). This transformation maps the point y = ∞ to z = 0 and y = −u to z = K(s2), and ψm ∼ zm+ 1 2 at z → 0, ψm ∼ (K − z) 1 2 at z → K. In the IR limit u→ −∞, K → π 2 , this equation can be solved exactly in terms of the Jacobi polynomials (cos z)m sin 2zP (m,0) j (cos 2z). When the IR limit of RG is described by CFT, the values ∆i = (ei−e0) 24 coincide with the spectrum of conformal dimensions of primary fields and d− e0 with the central charge of CFT. In our case ∆j,m = ν ( κ′m,j − κ′0,0 ) 24 = j(j + 1) N − m2 4N , j ≤ m, e0 = 6 N . These values correspond in one loop approximation to the spectrum of ZN -parafermionic CFT. It can be proved [16] that perturbation theory in s2 = 1 1+e−4u for eigenvalues converges for all real u. The eigenvalues κ′m,j can be expanded in the series in parameter e4u = (MR)−4/N . We will see later that corresponding quantum (all loops) series have the IR expansion parameter (MR)− 4 N+2 . For example, κ′m,j − κ′0,0 6 = 4j(j + 1)−m2 − (4j(j + 1)−m2)2 8j(j + 1) s2 + · · · , (7.4) κ′0,0 = 6− s4 − 1 2 s6 + · · · = 6− e8u + 3 2 e12u + · · · . (7.5) In the opposite UV limit u � 1 the potential term in (7.3) with exponential accuracy has the form Vl(z) = − 1 sinh2 2z +m2 coth2 z, 0 < z � K, Vr(z1) = − 1 sinh2 2z1 +m2 tanh2 z1, 0 < z1 = K − z � K. (7.6) Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 17 −5 0 5 10 10 2 10 3 u E = κ /6 21 69 125 189 261 Figure 6. Ricci flow of the levels from IR to UV for m = 10. In the right region the potential V is attractive for m > 0 and has a bound states ψm,j = (tanh z1) 1 2 (cosh z1)j−m+1F ( −j,−j +m,m− 2j, cosh−2 z1 ) , (7.7) 1 6 κ′m,j = m2 − (2j + 1−m)2, j = 0, . . . ≤ m− 1 2 . (7.8) These states describe discrete degrees of freedom of the manifold which survive in the UV limit. We note that UV limit is described by the SL(2,R)/U(1) CFT which was studied in [10]. The levels (7.8) correspond to discrete series representations of SL(2,R) and play an essential role for string theory interpretation of the coset CFT. In the left region the potential V is repulsive and for j > m−1 2 the spectrum can be derived by matching the exact solutions at the left and right ends ψ(l) m = Nl(tanh z)m+ 1 2 (cosh z)2ipF ( A,A,m+ 1, tanh2 z ) , ψ(r) m = Nr(tanh z1) 1 2 (cosh z1)2ipF ( A,A−m, 1, tanh2 z1 ) (here as before A = m+1−2ip 2 ) with the plane wave in the middle. The reflection amplitude R (cl) l will be again (6.5) and R (cl) r is now R′(cl)r = Γ(1 + 4ip)Γ ( 1 2 − 2ip+ m 2 ) Γ ( 1 2 − 2ip− m 2 ) Γ(1− 4ip)Γ ( 1 2 + 2ip+ m 2 ) Γ ( 1 2 + 2ip− m 2 ) . (7.9) The matching leads to κ′m,j(u) 6 = m2 + π2(2j −m+ 2) 16(u+ rm)2 +O ( 1/u5 ) . (7.10) The flow of the spectrum for m = 10 from IR to UV, i.e., from discrete spectrum for u→ −∞ to discrete (7.8) and continuum (7.10) for u → −∞ is shown on the Fig. 6. One can see that not only the ground state level e0(R) (related with effective central charge c(R) = 2− e0(R)) is according to Zamolodchikov’s c-theorem the decreasing (non-increasing) function of u, but all levels also possess this property. 18 V.A. Fateev The quantum version of the reflection amplitude (7.9) is R(q) r = ( MR 16πb2 )−2iP/b Γ(1 + 4biP )Γ(1 + iP/b) Γ(1− 4biP )Γ(1− iP/b) Γ ( 1 2 − 2biP + m 2 ) Γ ( 1 2 − 2biP − m 2 ) Γ ( 1 2 − 2biP + m 2 ) Γ ( 1 2 − 2biP − m 2 ) . The poles of R (q) r (P,m) at the physical strip iP ≥ 0 at the points Pj,m = i 4b(m − 2j − 1), j ≤ m−1 2 , determine exact bound states levels ( 2b2 = 2a2 − 1 = 1 2ν − 1 ) 1 6 em,j = ( m2 k + 4P 2 m,j ) = ν ( m2 − 1 1− 2ν (m− 2j − 1) ) in agreement with (7.8) up to O(ν2). The minisuperspace approach is valid for the quantum numbers j,m � k = 4a2. In the UV limit MSM looks as a cigar matched with a trumpet. The CFTs corresponding to these sigma models are T dual. Both of these models are dual to S-L CFT, but interpretation of the primary fields (2.4) is different. The numbers m, n (momentum m and winding quantum number n for cigar) transform to n, m (momentum n and winding quantum number m for trumpet). This transformation corresponds to φ → φ̂, where ∂µφ̂ = εµν∂vφ. The reflection amplitudes R (q) l (p,m) and R (q) r (p,m) correspond to the momentum number equal to m and winding number equal to 0 for cigar and vice versa for trumpet. It means that left (ϕ → ∞) and right (ϕ→ −∞) CFTs are related by transformation φ→ φ̂, i.e., the potential term in the action of QFT dual to MSM is 2µebϕ cos(aφ) + 2µe−bϕ cos ( aφ̂ ) . But these two terms are mutually local only if 4a2 = k is integer, i.e., k = N , and we derive again the quantization of the coupling constant. 8 ZN -parafermionic CFT and IR action for Ricci flow ZN -parafermionic CFT [42] with the central charge cN = 2− 6 N+2 describes the critical behavior of ZN -Ising model [18]. It has the primary fields φj,m, j ≤ m, with the conformal dimensions ∆ (CFT) j,m = j(j + 1) N + 2 − m2 4N . Besides the parafermionic symmetry it has also the symmetry generated by WN algebra. The ZN -neutral fields are thermal operators φj,0 with ∆ (CFT) j,0 = j(j+1) N+2 , j = 1, . . . ≤ [N/2]. To show that the Ricci flow, studied in the previous section, in the IR regime is described by the perturbation of the ZN -parafermionic CFT, one should find the receiving operator in the space of the ZN -neutral fields of this theory. The perturbative calculations with this IR relevant field must be consistent with RG results. Besides the parafermionic symmetry ZN -parafermionic CFT has the symmetry algebra WN . This symmetry algebra is generated by the holomorphic field Ws(z) which appear in the OPE of the parafermionic currents ψ(z) and ψ∗(z) (see [11]). The first thermal operator ε = φj,0 has the descendent field E = NW−1W−1ε with dimension 1+ 2 N+2 . The constantN provides the conformal normalization of the field E. This field is unique self dual (with respect ZN ⊗ ẐN or order-disorder duality) integrable IR relevant perturbation in ZN -parafermionic CFT. It means that the action describing our flow should be written as AIR = APF + κ ∫ Ed2x, (8.1) Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 19 where APF is the action of ZN -parafermionic CFT and κ is the coupling constant. The exact relation between κ and mass scale M , which appear later in FST and TBA equations, can be derived by BA method [12, 40] and is (πκ)2 = N2(N − 2)2 3(N + 2)2(N + 4)2 G(w)G(3w) [ 4 wM ]8w , (8.2) where G(w) = Γ(1+w) Γ(1−w) and w = 1 N+2 . One can calculate the IR corrections to the spectrum ∆ (CFT) j,m and to the effective central charge c(R) with the action (8.1), (8.2). The first exact corrections to Dj,m = (N + 2)∆ (CFT) j,m is Dj,m(R) = Dj,m − 1 4 D2 j,m B(j, w) j(j + 1) ( 8π wMR )4w + · · · , (8.3) where B(j, w) = 2N2G2(w)G((2j + 2)w) (N + 2)2G(2w)G(2jw) . The exact corrections to the central charge calculated with the action AIR are c = 2− 6 N + 2 + C1(w) ( 8π wMR )8v + C2(w) ( 8π wMR )12v + · · · , (8.4) where C1(w) = wN2(N − 2)2G(w)G(3w) (N + 2)2(N + 4)2G(4w)G(−2w) , C2(w) = −w3N4(N − 4)2G(2w)G(4w) 2(N + 4)4(N + 8)2G(6w)G(−3w) . At N � 1, w = 1 N+2 � 1 the coefficients Bj,m, C1, C2 are Bj,m = 2 + O(w), C1(w) = 1 +O(w), C3(w) = −3 2 +O(w). Comparing equations (8.3), (8.4) with (7.4), (7.5) we see their coincidence in one loop approximation. To make more non-trivial test one can use the TBA equations for MSM. These equations can be derived from the massless FST, consistent with QFTs (7.2), (8.1). Massless FSTs are widely used for the analysis of RG flows from one critical point in UV to another critical point in IR (see, for example, [17, 43]). The massless particles or kinks in such FST are of two kinds: right-moving with the dispersion low: e = p = M 2 e θ and left-moving: e = −p = M 2 e −θ. The full scattering matrix contains amplitudes SRR(θ), SLL(θ) and SRL(θ) of right-right, left-left and right-left moving particles. ZN -parafermionic CFT which is the basic object for IR action (8.1) possesses the symmetry with quantum group SL(2)q with q = exp ( 2πi N+2 ) . As the parameter of symmetry q takes only discrete values it is natural to expect that the scattering matrix will correspond to the massless kinks. The most suitable factorized scattering matrix of kinks with SL(2)q symmetry is described in [11], where all amplitudes of kinks scattering are written explicitly. In [11] this scattering matrix was used for massive kinks in some integrable model also related with ZN -parafermionic CFT. Here one should use the same amplitudes for the scattering of right-right, left-left and right-left moving kinks. The TBA equations can be derived by the procedure of diagonalization of the transfer-matrix with the elements depending on the scattering amplitudes. The massless FST described above 20 V.A. Fateev Figure 7. Incidence diagram of TBA system and source terms for MSM. leads to the same equations (6.7) for N + 1 functions εa, but the source term ρa is different. Now it is ρa = Mδa0 2 eβ + MδaN 2 e−β. The numerical solution of TBA equations perfectly reproduces the UV and the IR behavior of MSM in the scaling limit (see [16]). The exact coefficients B(j, w), C1(w), C2(w) derived from the action (8.1) coincide with all possible numerical accuracy with the corresponding coefficients calculated from the TBA equations. 9 Concluding remarks 1. Sine-Liouville CFT possesses integrable perturbations, corresponding to massive and mass- less QFTs. All these perturbations establish non-trivial duality properties, like Dirac fermion-charged boson duality, duality with sigma models, which describe “massive” and “massless” Ricci flows. 2. Sine-Liouville CFT can be generalized to sine-Toda CFT. This CFT possesses three different integrable perturbations [14]. These integrable field theories have the Lagrangian description in terms of massive Thirring model coupled with non-simply laced affine Toda theories of rank r. Perturbative calculations, analysis of FST and BA technique show that these QFTs have the dual description available for the perturbative analysis in the strong coupling regime. The dual QFTs are formulated in terms of completely bosonic theories, namely, complex sinh-Gordon theory coupled with Toda theories corresponding to dual affine algebras but with smaller rank r̂ = r − 1. 3. The SSM can be generalized to sigma-model with 3d target space [15]. The metric of this sigma model is the deformation of O(4) (or chiral SU(2)⊗SU(2)) metric, depending on two parameters. The two-parameter family of dual QFTs describes the wide class of integrable theories. Different reductions of these theories with respect two quantum groups describe almost all known integrable field theories with cUV ≤ 3. See also recent papers [3, 24, 26]. 4. The scattering matrix (4.14), which can be considered as non-perturbative definition of SSM is related with massless scattering theory for MSM. The second can be derived by SL(2)q restriction with q = exp ( i 2π N+2 ) of the S-matrix (4.14) for the value of parameter λ = 1 N+2 . Such restriction of scattering matrix of particles (4.14) (which possesses the quantum group symmetry with q = exp(i2πλ)) to S-matrix of kinks is possible only for integer N . The similar phenomenon takes place in the sigma model with 3d target space. There also the scattering matrices for “massive” Ricci flow and massless one are related in the similar way. Probably this property is general for integrable Ricci flows, which are related by simple transformation of the metric similar to (5.3), (7.2), but describe completely different physics. 5. The large distance pattern of sigma-models depends strongly on other possible terms in action (5.1), which are denoted as . . . . The fields like the tachion, the Wess–Zumino– Witten term or the topological charge are usually less important in the UV behavior of Integrable Deformations of Sine-Liouville Conformal Field Theory and Duality 21 theory. However, if the QFT corresponding to sigma model has broken P, T symmetries (but not PT) the action of sigma model contains the terms like B-field or some higher differential forms consistent with metric. These terms appear in the Ricci flow equations and can be relevant in UV regime. 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