Saved in:
Bibliographic Details
Main Authors: You, Jinxiang, Wang, Shaojie
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.00715
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913374054383616
author You, Jinxiang
Wang, Shaojie
author_facet You, Jinxiang
Wang, Shaojie
contents Since the DIII-D resonant magnetic perturbation experiment [Nucl. Fusion $\bm{59}$, 126010 (2019)] suggests that the neoclassical toroidal viscosity due to the collisional effects associated with the non-resonant magnetic perturbations is not enough to explain the observed toroidal rotation, it is of interest to investigate the toroidal rotation induced by the anomalous diffusion due to the resonant magnetic perturbations. Gyrokinetic simulation of the toroidal rotation of plasma in a stochastic magnetic field is carried out to investigate the resonant magnetic perturbations effects on toroidal rotation. The simulation results suggest that, in a stochastic magnetic field, resonant magnetic perturbations drive the plasma to toroidally rotate through the ambipolar radial electric field. It is found that this spontaneous flow driven on the time scale less than an ion-ion collision time is the parallel return flow of the $\bm{E}_r\times\bm{B}_0$ drift, which is due to the the ambipolar radial electric field induced by the non-ambipolar radial diffusion in the stochastic magnetic field. Collisional effect changes the plasma toroidal rotation from the return flow to the rigid-body flow after a few ion-ion collision times. The toroidal rotation observed in DIII-D resonant magnetic perturbation experiment [Nucl. Fusion $\bm{59}$, 126010 (2019)], can be explained by the rigid-body rotation driven by the ambipolar radial electric field generated by the stochastic magnetic field layer.
format Preprint
id arxiv_https___arxiv_org_abs_2406_00715
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Gyrokinetic simulation of the spontaneous toroidal rotation of plasma in a stochastic magnetic field
You, Jinxiang
Wang, Shaojie
Plasma Physics
Since the DIII-D resonant magnetic perturbation experiment [Nucl. Fusion $\bm{59}$, 126010 (2019)] suggests that the neoclassical toroidal viscosity due to the collisional effects associated with the non-resonant magnetic perturbations is not enough to explain the observed toroidal rotation, it is of interest to investigate the toroidal rotation induced by the anomalous diffusion due to the resonant magnetic perturbations. Gyrokinetic simulation of the toroidal rotation of plasma in a stochastic magnetic field is carried out to investigate the resonant magnetic perturbations effects on toroidal rotation. The simulation results suggest that, in a stochastic magnetic field, resonant magnetic perturbations drive the plasma to toroidally rotate through the ambipolar radial electric field. It is found that this spontaneous flow driven on the time scale less than an ion-ion collision time is the parallel return flow of the $\bm{E}_r\times\bm{B}_0$ drift, which is due to the the ambipolar radial electric field induced by the non-ambipolar radial diffusion in the stochastic magnetic field. Collisional effect changes the plasma toroidal rotation from the return flow to the rigid-body flow after a few ion-ion collision times. The toroidal rotation observed in DIII-D resonant magnetic perturbation experiment [Nucl. Fusion $\bm{59}$, 126010 (2019)], can be explained by the rigid-body rotation driven by the ambipolar radial electric field generated by the stochastic magnetic field layer.
title Gyrokinetic simulation of the spontaneous toroidal rotation of plasma in a stochastic magnetic field
topic Plasma Physics
url https://arxiv.org/abs/2406.00715