Your search keyword '"Wang, Z. X."' showing total 4 results

1. Kinetic calculation of the resistive wall mode and fishbone-like mode instability in tokamak.

Author

Hao, G. Z., Yang, S. X., Liu, Y. Q., Wang, Z. X., Wang, A. K., and He, H. D.

Subjects

KINETIC theory of gases, FISHBONE instability, PLASMA gases, TOKAMAKS, PARTICLE dynamics analysis

Abstract

Kinetic effects of both trapped thermal and energetic particles on the resistive wall mode (RWM) and on the fishbone-like mode (FLM) are investigated in theory. Here, the trapped thermal particles include both ions and electrons. The FLM is driven by trapped energetic particles. The results demonstrate that thermal particle collisions can either stabilize or destabilize the RWM, depending on the energetic particle pressure βh. Furthermore, the critical value of βh for triggering the FLM is increased when the thermal particle contribution is taken into account. The critical value sensitively depends on the plasma collision frequency. In addition, the plasma inertia is found to have a negligible influence on the FLM. [ABSTRACT FROM AUTHOR]

Published

2016

2. Unstable domains of tearing and Kelvin-Helmholtz instabilities in a rotating cylindrical plasma.

Author

Fan, D. M., Wei, L., Wang, Z. X., Zheng, S., and Duan, P.

Subjects

PLASMA instabilities, MAGNETOHYDRODYNAMICS, PLASMA gases, ROTATIONAL motion, NUMERICAL analysis

Abstract

Effects of poloidal rotation profile on tearing and Kelvin-Helmholtz (KH) instabilities in a cylindrical plasma are investigated by using a reduced magnetohydrodynamic model. Since the poloidal rotation has different effects on the tearing and KH modes in different rotation regimes, four unstable domains are numerically identified, i.e., the destabilized tearing mode domain, stabilized tearing mode domain, stable-window domain, and unstable KH mode domain. It is also found that when the rotation layer is in the outer region of the rational surface, the stabilizing role of the rotation can be enhanced so significantly that the stable window domain is enlarged. Moreover, Alfven resonances can be induced by the tearing and KH modes in such rotating plasmas. Radially wide profiles of current and vorticity perturbations can be formed when multiple current sheets on different resonance positions are coupled together. [ABSTRACT FROM AUTHOR]

Published

2014

3. Magnetic-island-induced ion temperature gradient mode.

Author

Wang, Z. X., Li, J. Q., Kishimoto, Y., and Dong, J. Q.

Subjects

*PLASMA gases, *ELECTROMAGNETIC fields, *PLASMA waves, *TEMPERATURE inversions, *PLASMA dynamics

Abstract

Characteristics of ion temperature gradient (ITG) instability in the presence of a magnetic island are investigated numerically using a gyrofluid model. It is shown that when the magnetic island is wide enough to produce a broad distribution of rational surfaces near the O-point region, the ITG perturbations at these rational surfaces form a radially global-type eigenmode with a fast growth rate, which is referred to as the magnetic-island-induced ITG mode. Moreover, the magnetic island also causes both radial and poloidal mode couplings, which play a stabilizing role. [ABSTRACT FROM AUTHOR]

Published

2009

4. Verification of particle simulation of radio frequency waves in fusion plasmas.

Author

Kuley, Animesh, Wang, Z. X., Lin, Z., and Wessel, F.

Subjects

*RADIO frequency, *FUSION (Phase transformation), *PLASMA gases, *COMPUTER simulation, *VLASOV equation, *ELECTRONS, *PREDICTION models

Abstract

Radio frequency (RF) waves can provide heating, current and flow drive, as well as instability control for steady state operations of fusion experiments. A particle simulation model has been developed in this work to provide a first-principles tool for studying the RF nonlinear interactions with plasmas. In this model, ions are considered as fully kinetic particles using the Vlasov equation and electrons are treated as guiding centers using the drift kinetic equation. This model has been implemented in a global gyrokinetic toroidal code using real electron-to-ion mass ratio. To verify the model, linear simulations of ion plasma oscillation, ion Bernstein wave, and lower hybrid wave are carried out in cylindrical geometry and found to agree well with analytic predictions. [ABSTRACT FROM AUTHOR]

Published

2013