Effects of plasma nonuniformity on zero frequency zonal structure generation by drift Alfven wave instabilities in toroidal plasmas

TL;DR

This paper investigates how plasma nonuniformity influences the generation of zero frequency zonal structures by drift Alfven wave instabilities in toroidal plasmas, using nonlinear gyrokinetic theory to derive governing equations and analyze different scenarios.

Contribution

It introduces a comprehensive nonlinear gyrokinetic framework accounting for self-beating and radial modulation of DAWs, advancing understanding of ZFZS generation in nonuniform plasmas.

Findings

ZFZS excitation by KBM is sensitive to plasma parameters

Derived nonlinear dispersion relation for ZFZS in toroidal plasmas

Identified need for further study on KBM nonlinear saturation

Abstract

Effects of plasma nonuniformity on zero frequency zonal structure (ZFZS) excitation by drift Alfven wave (DAW) instabilities in toroidal plasmas are investigated using nonlinear gyrokinetic theory. The governing equations describing nonlinear interactions among ZFZS and DAWs are derived, with the contribution of DAWs self-beating and radial modulation accounted for on the same footing. The obtained equations are then used to derive the nonlinear dispersion relation, which is then applied to investigate ZFZS generation in several scenarios. In particular, it is found that, the condition for zonal flow excitation by kinetic ballooning mode (KBM) could be sensitive to plasma parameters, and more detailed investigation is needed to understand KBM nonlinear saturation, crucial for bulk plasma transport in future reactors.