Second-order multisymplectic field theory: A variational approach to second-order multisymplectic field theory

TL;DR

This paper develops a geometric-variational framework for second-order multisymplectic field theories, extending existing formalisms and applying them to the Camassa-Holm equation in continuous and discrete contexts.

Contribution

It generalizes the multisymplectic form formula to second-order theories within a Lagrangian framework and introduces a multisymplectic-momentum integrator for nonlinear PDEs.

Findings

Derived the multisymplectic structure from the action variation.

Extended the Noether theorem to second-order field theories.

Created a multisymplectic integrator for the Camassa-Holm equation.

Abstract

This paper presents a geometric-variational approach to continuous and discrete {\it second-order} field theories following the methodology of \cite{MPS}. Staying entirely in the Lagrangian framework and letting $Y$ denote the configuration fiber bundle, we show that both the multisymplectic structure on $J^3Y$ as well as the Noether theorem arise from the first variation of the action function. We generalize the multisymplectic form formula derived for first order field theories in \cite{MPS}, to the case of second-order field theories, and we apply our theory to the Camassa-Holm (CH) equation in both the continuous and discrete settings. Our discretization produces a multisymplectic-momentum integrator, a generalization of the Moser-Veselov rigid body algorithm to the setting of nonlinear PDEs with second order Lagrangians.