Second order nonlinear gyrokinetic theory : From the particle to the gyrocenter

TL;DR

This paper presents a systematic derivation of second-order nonlinear gyrokinetic equations using a two-step approach, accommodating arbitrary background magnetic field strength and focusing on electromagnetic fluctuations.

Contribution

It introduces a self-contained, systematic derivation of second-order nonlinear gyrokinetic equations without assumptions on background magnetic field amplitude, extending previous methods.

Findings

Explicit second-order electromagnetic gyrokinetic equations derived.

Two-step transformation approach detailed and applied.

No assumptions on background magnetic field amplitude.

Abstract

A gyrokinetic reduction is based on a specific ordering of the different small parameters characterizing the background magnetic field and the fluctuating electromagnetic fields. In this tutorial, we consider the following ordering of the small parameters: $\epsilon\_B=\epsilon\_\delta^2$ where $\epsilon\_B$ is the small parameter associated with spatial inhomogeneities of the background magnetic field and $\epsilon\_\delta$ characterizes the small amplitude of the fluctuating fields. In particular, we do not make any assumption on the amplitude of the background magnetic field. Given this choice of ordering, we describe a self-contained and systematic derivation which is particularly well suited for the gyrokinetic reduction, following a two-step procedure. We follow the approach developed in [Sugama, Physics of Plasmas 7, 466 (2000)]:In a first step, using a translation in velocity, we embed the transformation performed on the symplectic part of the gyrocentre reduction in the guiding-centre one. In a second step, using a canonical Lie transform, we eliminate the gyroangle dependence from the Hamiltonian. As a consequence, we explicitly derive the fully electromagnetic gyrokinetic equations at the second order in $\epsilon\_\delta$.