Affiliation:
1. Carolina Center for Interdisciplinary Applied Mathematics Department of Mathematics University of North Carolina at Chapel Hill Chapel Hill North Carolina USA
Abstract
AbstractWave propagation in the form of fronts or kinks, a common occurrence in a wide range of physical phenomena, is studied in the context of models defined by their Hamiltonian structure. Motivated, for dispersive wave evolution equations such as a strongly nonlinear model of two‐layer internal waves in the Boussinesq limit, by the symmetric properties of a class of front‐propagating solutions, known as conjugate states or solibores, a generalized formulation based purely on the dispersionless reduction of a system is introduced, and a class of undercompressive shock solutions, here referred to as “Hamiltonian shocks,” is defined. This analysis determines whether a Hamiltonian shock, representing locally a kink for the parent dispersive equations, will interact with a sufficiently smooth background wave without inducing loss of regularity, which would take the form of a classical dispersive shock for the parent equations. This property is also related to an infinitude of conservation laws, drawing a parallel to the case of completely integrable systems.
Funder
Isaac Newton Institute for Mathematical Sciences
Engineering and Physical Sciences Research Council
Office of Naval Research
National Science Foundation
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