Derivation of a -Symmetric Sine-Gordon Model from a Nonequilibrium Spin-Boson System via Keldysh Functional Integrals

Abstract

We present a microscopic derivation from a nonequilibrium spin-boson model to a -symmetric non-Hermitian sine-Gordon (SG) effective theory, via the Keldysh functional-integral formalism, a Lang-Firsov polaron transformation, bosonization, and a Grassmann coherent-state spin trace.The spin trace yields the generic reduced vertex gr(λ1)+igi(λ1), where the imaginary part originates from the nonequilibrium Keldysh distribution asymmetry δ n(ω)=n+(ω)-n-(ω). We provide an explicit dictionary between the spin-boson microscopic parameters and the NH-SG couplings: K=vf/J2 (Luttinger parameter from J), gr J2/ (from the transverse coupling and impurity width), and I=gi/grμ/vf (bias ratio, an exact RG invariant).One-loop Wilson momentum-shell RG on the NH-SG action gives the closed equations K/ l=-gr2(1-I2)K2 and gr/ l=(2-K)gr, identical to those of Ashida et al.\ for the -symmetric SG; the present work supplies the microscopic initial conditions from the spin-boson Keldysh reduction. The BKT separatrix K=2 (Toulouse line), the EP fixed manifold I=1 (μ=μc), and the mass gap m e-c/K0-2 all follow from this closed system.In the non-relativistic soliton sector near the EP, the effective coupling g=gr1-I2 reduces the S-matrix to the Lieb-Liniger rational form and the Bethe ansatz becomes exact for that auxiliary gas.Within this sector we derive n-string bound states withEn bind=-n(n2-1)g2/12, identify the EP as the many-body bound-state threshold, and construct the Jordan-partner state from the ε-regularised dimer.

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…