Gyrokinetic simulation on the energetic-particle-induced geodesic acoustic mode

Miki, Kazuhiro; Idomura, Yasuhiro   

Understanding of the energetic particles physics is of great interest in the future burning plasmas. Particularly, particle loss in the presence of EGAM may be critical for ITER. We here introduce energetic particles in a full-f gyrokinetic code (GT5D). (1) We find linear dynamics of the EGAM driven by bump-on-tail particle distributions. We examine flat-q, homogeneous, axisymmetric, electrostatic gyrokinetic simulations. We note that a sufficient resolution on the parallel velocity space is essential to reproduce the EGAM excitation. Above a certain level of the beam intensity, an oscillatory mode grows with about a half of the standard GAM. The observed frequencies are consistent with the eigenmode analyses derived from the perturbed gyrokinetic equations. The theoretical analyses also indicate a bifurcation of the excited modes depending on q-value. An estimation of the finite-orbit-width effects leads us to the reduction of the growth rate. (2) We find linear dynamics of the EGAM driven by slowing-down distributions. We examine the axisymmetric gyrokinetic simulations with DIII-D-like parameters. The observed growth rates and frequencies are consistent with results of other hybrid code.