Gross-Neveu model with O(2)$_L\times$O(2)$_R$ chiral symmetry: Duality with Zakharov-Mikhailov model and large $N$ solution

TL;DR

This paper introduces a novel four-fermion model with O(2) chiral symmetry, demonstrating its duality to an integrable model, and solves it in the large N limit to explore competing condensates and soliton dynamics.

Contribution

It constructs a new O(2) chiral Gross-Neveu model, establishes its duality with the Zakharov-Mikhailov model, and solves it analytically at large N, revealing rich phase structure and soliton solutions.

Findings

Duality between O(2) chiral Gross-Neveu and Zakharov-Mikhailov models

Exact large N solution with explicit soliton solutions

Identification of a 'perfect' Gross-Neveu model with full Pauli-Gürsey symmetry

Abstract

The two-flavor Gross-Neveu model with U(2)$_L\times$U(2)$_R$ chiral symmetry in 1+1 dimensions is used to construct a novel variant of four-fermion theories with O(2)$_L\times$O(2)$_R$ chiral symmetry. The spontaneous breaking of the group O(2), a continuous group with two connected components (rotations and reflections), gives rise to new phenomena. It is ideally suited to describe a situation where two distinct kinds of condensation compete, in particular chiral symmetry breaking (particle-hole condensation) and Cooper pairing (particle-particle condensation). After solving the O(2) chiral Gross-Neveu model in detail, we demonstrate that it is dual to another classically integrable model due to Zakharov and Mikhailov. The duality enables us to solve the quantum version of this model in the large $N$ limit with semiclassical methods, supporting its integrability at the quantum level. The resulting model is the unique four-fermion theory sharing the full Pauli-G\"ursey symmetry with free, massless fermions (``perfect Gross-Neveu model") and provides us with a solvable model for competing chiral and Cooper pair condensates, including explicit soliton dynamics and the phase diagram.