Ponderomotive forces and wave dispersion: two sides of the same coin

TL;DR

This paper presents a unified theoretical framework linking ponderomotive forces and wave dispersion across various plasma and atomic environments, emphasizing their fundamental connection through wave-particle interactions.

Contribution

It introduces a general adiabatic Lagrangian approach that describes nonlinear ponderomotive effects and wave dispersion in diverse physical settings.

Findings

Unified description of wave-particle interactions

Derivation of nonlinear dispersion relations

Connection between ponderomotive forces and wave properties

Abstract

Presented here is a general view on adiabatic and resonant wave-particle interactions leading to a uniform description of nonlinear ponderomotive effects in very different environments, from low-temperature plasmas to relativistic plasmas or even atoms in laser light. Treating the wave-particle interaction as a classical mode-coupling problem, this theory shows the inherent connection between the ponderomotive forces and the properties of waves causing those forces. The adiabatic Lagrangians are derived for single particles and nonlinear waves, possibly carrying trapped particles, and yield both the dynamic equations and the nonlinear dispersion relations in the general case.