Nonlinear adiabatic electron plasma waves. I. General theory and nonlinear frequency shift

TL;DR

This paper develops a comprehensive nonlinear theory for electron plasma waves under adiabatic conditions, accounting for various complex effects and providing insights into frequency shifts in inhomogeneous, non-stationary plasmas.

Contribution

It introduces a self-consistent nonlinear framework for electron plasma waves that includes effects like separatrix crossing and phase velocity changes, extending previous models.

Findings

Derivation of the nonlinear frequency shift considering multiple effects.

Analysis of the importance of each effect based on wave parameters.

Framework applicable to inhomogeneous and non-stationary plasmas.

Abstract

This paper provides a complete self-consistent nonlinear theory for electron plasma waves, within the framework of the adiabatic approximation. The theory applies whatever the variations of the wave amplitude, provided that they are slow enough, and it is also valid when the plasma is inhomogeneous and non stationary. Moreover, it accounts for: (i) the geometrical jump in action resulting from separatrix crossing; (ii) the continuous change in phase velocity making the wave frame non-inertial; (iii) the harmonic content of the scalar potential ; (iv) a non-zero vector potential ; (v) the transition probabilities from one region of phase space to the other when an orbit crosses the separatrix ; (vi) the possible change in direction of the wavenumber. The relative importance of each of the aforementioned effects is discussed in detail, based on the derivation of the nonlinear frequency shift. This allows to specify how the general formalism may be simplified, depending on the value of the wavenumber normalized to the Debye length. Specific applications of our theory are reported on the companion paper.