On higher order passivity preserving schemes for nonlinear Maxwell's equations

TL;DR

This paper introduces two advanced discretization schemes for nonlinear Maxwell's equations that preserve passivity and energy properties, ensuring accurate and stable simulations in nonlinear Kerr media.

Contribution

It proposes two novel variational approximation methods for higher order passivity preservation in nonlinear Maxwell's equations, with rigorous energy conservation proofs.

Findings

Methods achieve order optimal convergence rates in nonlinear problems.

Schemes coincide with known mixed finite element and Runge-Kutta methods for linear media.

Numerical tests confirm theoretical convergence and passivity properties.

Abstract

We present two strategies for designing passivity preserving higher order discretization methods for Maxwell's equations in nonlinear Kerr-type media. Both approaches are based on variational approximation schemes in space and time. This allows to rigorously prove energy conservation or dissipation, and thus passivity, on the fully discrete level. For linear media, the proposed methods coincide with certain combinations of mixed finite element and implicit Runge-Kutta schemes. The order optimal convergence rates, which can thus be expected for linear problems, are also observed for nonlinear problems in the numerical tests.