Convergence of a quantum lattice Boltzmann scheme to the nonlinear Dirac equation for Gross-Neveu model in $1+1$ dimensions

TL;DR

This paper proves that a quantum lattice Boltzmann scheme converges to the strong solution of the nonlinear Dirac equations for the Gross-Neveu model in 1+1 dimensions, ensuring numerical stability and accuracy.

Contribution

It introduces a convergence proof for the quantum lattice Boltzmann scheme applied to the nonlinear Dirac equations, using a Glimm type functional for stability analysis.

Findings

Convergence of the scheme to the nonlinear Dirac equation solutions.

Stability estimates established via a Glimm type functional.

Solutions form a compact set, ensuring convergence.

Abstract

This paper studies the quantum lattice Boltzmann scheme for the nonlinear Dirac equations for Gross-Neveu model in $1+1$ dimensions. The initial data for the scheme are assumed to be convergent in $L^2$. Then for any $T\ge 0$ the corresponding solutions for the quantum lattice Boltzmann scheme are shown to be convergent in $C([0,T];L^2(R^1))$ to the strong solution to the nonlinear Dirac equations as the mesh sizes converge to zero. In the proof, at first a Glimm type functional is introduced to establish the stability estimates for the difference between two solutions for the corresponding quantum lattice Boltzmann scheme, which leads to the compactness of the set of the solutions for the quantum lattice Boltzmann scheme. Finally, the limit of any convergent subsequence of the solutions for the quantum lattice Boltzmann scheme is shown to coincide with the strong solution to a Cauchy problem for the nonlinear Dirac equations.