Solitons in lattice field theories via tight-binding supersymmetry

TL;DR

This paper develops a lattice supersymmetry framework to construct and analyze solitons in discrete field theories, connecting reflectionless potentials with lattice models of superconductivity and deriving new trace identities for the discrete Dirac operator.

Contribution

It introduces a novel lattice supersymmetry approach for solitons, including new trace identities for the discrete Dirac operator, and explicitly constructs soliton solutions in lattice Gross-Neveu models.

Findings

Lattice solitons correspond to reflectionless potentials in the discrete scattering problem.

A matrix transformation maps tight-binding models to isospectral models with identical scattering properties.

Explicit topological and non-topological soliton solutions are computed with their bound state spectra.

Abstract

Reflectionless potentials play an important role in constructing exact solutions to classical dynamical systems, non-perturbative solutions of various large-N field theories, and closely related solitonic solutions to the Bogoliubov-de Gennes equations in the theory of superconductivity. These solutions rely on the inverse scattering method, which reduces these seemingly unrelated problems to identifying reflectionless potentials of an auxiliary one-dimensional quantum scattering problem. There are several ways of constructing these potentials, one of which is quantum mechanical supersymmetry (SUSY). In this paper, motivated by recent experimental platforms, we generalize this framework to develop a theory of solitons in lattice versions of interacting field theories. Our analysis hinges on the use of trace identities, which are relations connecting the potential of an equation of motion to the scattering data. For a discrete Schr\"odinger operator, such trace identities are well known, and we derive a new set of identities for the discrete Dirac operator. We then use these in a lattice Gross-Neveu and chiral Gross-Neveu (Nambu-Jona-Lasinio) model to show that lattice solitons correspond to reflectionless potentials associated with the discrete scattering problem. These models are of significance as they are equivalent to a mean-field theory of a lattice superconductor. To explicitly construct these solitons, we generalize supersymmetric quantum mechanics to tight-binding models. We show that a matrix transformation exists that maps a tight-binding model to an isospectral one which shares the same structure and scattering properties. The corresponding soliton solutions have both modulated hopping and onsite potential; we explicitly compute both topological and non-topological soliton solutions as well as bound state spectra in the aforementioned models.