Frequency Chirping of Energetic-Particle-Driven Geodesic Acoustic Modes in Tokamaks

TL;DR

This paper investigates the nonlinear dynamics and frequency chirping of energetic-particle-driven geodesic acoustic modes (EGAMs) in tokamaks using gyrokinetic simulations, revealing a linear scaling of chirping rate with linear growth rate.

Contribution

It provides a systematic gyrokinetic analysis of EGAM nonlinear saturation and frequency chirping, confirming theoretical predictions about chirping rate scaling.

Findings

Nonlinear saturation level scales quadratically with linear growth rate.

Frequency chirping rate scales linearly with linear growth rate.

Results are consistent with Chen-Zonca theoretical model.

Abstract

A suprathermal population of ions is present in tokamak plasmas due to external heating mechanisms and fusion reactions. These energetic particles (EP) can drive wave unstable, via inverse Landau damping. An example is the energetic-particledriven geodesic acoustic mode (EGAMs). In this work, we perform a systematic gyrokinetic investigation of the EGAM linear and nonlinear dynamics, using the global gyrokinetic particle-in-cell code ORB5. The nonlinear saturation given by the EP redistribution in phase space is characterized by a saturation level scaling quadratically with respect to the linear growth rate. The nonlinear EP dynamics in phase space has also effects on the EGAM frequency. To this extent, we investigate the frequency chirping, and we find that the chirping rate scales linearly with the linear growth rate over a wide range of EP concentrations. This scaling is consistent with the theoretical prediction of Chen-Zonca [L. Chen, and F. Zonca, Rev. Mod. Phys. 88, 015008 (2016)].