Your search keyword '"C. Z. Cheng"' showing total 2 results

1. Excitation of Alfvén cyclotron instability by charged fusion products in tokamaks

Author

C. Z. Cheng and N. N. Gorelenkov

Subjects

Physics, Tokamak, Astrophysics::High Energy Astrophysical Phenomena, Cyclotron, Condensed Matter Physics, Instability, Ion, law.invention, Physics::Plasma Physics, law, Excited state, Nuclear fusion, Atomic physics, Tokamak Fusion Test Reactor, Ion cyclotron resonance

Abstract

The spectrum of ion cyclotron emission (ICE) observed in tokamak experiments shows narrow peaks at multiples of the edge cyclotron frequency of background ions. A possible mechanism of ICE based on the fast Alfven Cyclotron Instability (ACI) resonantly excited by high energy charged products (α‐particles or protons) is presented here. Two‐dimensional eigenmode analysis of ACI mode structure and eigenfrequency are obtained in the large tokamak aspect ratio limit. The ACI is excited via wave‐particle resonances in phase space by tapping the fast ion velocity space free energy. The instability growth rates are computed perturbatively from the perturbed fast particle distribution function, which is obtained by integrating the high frequency gyrokinetic equation along the particle orbit. Numerical examples of ACI growth rates are presented for Tokamak Fusion Test Reactor (TFTR) [World Survey of Activities in Controlled Fusion Research [Nuclear Fusion special supplement 1991] (International Atomic Energy Agency...

Published

1995

2. Properties of low and medium frequency modes in two-fluid plasma

Author

C. Z. Cheng, Yueng-Kay Peng, and Akio Ishida

Subjects

Physics, Waves in plasmas, Magnetosonic wave, Mechanics, Condensed Matter Physics, Ion acoustic wave, Alfvén wave, Physics::Plasma Physics, Normal mode, Physics::Space Physics, Electromagnetic electron wave, Atomic physics, Phase velocity, Longitudinal wave

Abstract

Based on a two-fluid plasma model where the electron mass and the displacement current are neglected, the eigenmode properties such as the frequency and the compressibility are studied. It is found that these properties strongly depend on the two-fluid parameter kli, where k is the wave number of a mode and li is the ion skin depth. Especially it is found that as the two-fluid parameter kli increases beyond unity, the Alfven wave, which is an incompressible mode in the magnetohydrodynamics (MHD) limit, becomes compressible and its phase velocity approaches to the acoustic speed. The slow magnetosonic wave, which is compressible in the MHD limit, becomes incompressible as kli increases. Implications of these results are also discussed.

Published

2005