Your search keyword '"C. Z. Cheng"' showing total 4 results

1. Plasma shape effects on the Alfvén eigenmode spectrum through Alfvén slow-magnetosonic wave coupling

Author

G J Kramer and C Z Cheng

Subjects

Nuclear Energy and Engineering, Condensed Matter Physics

Abstract

The effect of the plasma shaping (triangularity and elongation) on the continuous spectrum, frequency gaps, and number of eigenmodes is studied. The plasma shaping affects the coupling between Alfvén and slow magnetosonic waves via the geodesic magnetic curvature and the plasma pressure. The Alfvén-slow coupling creates a large number of new gaps in the continuous spectrum below the Alfvén frequency where discrete modes can reside. In ideal magnetohydrodynamic simulations a large number (a few hundred or more) of potential eigenmodes are found. The number of eigenmodes is correlated with the maximum geodesic curvature and a minimum number of possible discrete eigenmodes is found at a negative triangularity of −0.3. It is hypothesized that these possible eigenmodes form a low amplitude and dense discrete spectrum, which can be studied experimentally.

Published

2022

2. ICRF results in D-T plasmas in JET and TFTR and implications for ITER

Author

Raffi Nazikian, Richard Hawryluk, Philip Efthimion, Gregory Hammett, Choong-Seock Chang, and C. Z. Cheng

Subjects

Jet (fluid), Tokamak, Materials science, Cyclotron, Plasma, Fusion power, Condensed Matter Physics, Ion, law.invention, Nuclear physics, Nuclear Energy and Engineering, Deuterium, Physics::Plasma Physics, law, Limiter, Atomic physics

Abstract

Recent experiments in D-T plasmas on the JET and TFTR tokamaks have evaluated a wide range of ITER relevant ion cyclotron heating scenarios. Absorption of fast waves at the second-harmonic tritium resonance has provided bulk ion heating in TFTR supershots and electron heating in JET H-mode discharges. In JET, deuterium minority heating has generated 1.7 MW of fusion power with 6 MW of radio frequency power giving a record steady-state Q-value of 0.22. Strong bulk ion heating has been achieved with He3 minority heating with central ion temperatures up to 13 keV being produced in H-modes with a density of 3.6 × 1019 m-3. Hydrogen, deuterium and He3 minority heating methods have produced plasmas with normalized confinement times greater than or equal to that required by ITER for ignition. These H-modes are characterized by small-amplitude, high-frequency ELMs, each of which transports less than 1.5% of the plasma energy content to the limiters. The heavy minority scheme of tritium in a deuterium plasma has been demonstrated both as a heating scheme and a generator of suprathermal neutrons. On TFTR mode conversion to an ion Bernstein wave has achieved central bulk ion heating in supershots with target ion temperatures greater than 20 keV.

Published

1998

3. Alpha-particle physics in the tokamak fusion test reactor DT experiment

Author

S J Zweben, V Arunasalam, S H Batha, R V Budny, C E Bush, S Cauffman, C S Chang, Z Chang, C Z Cheng, D S Darrow, R O Dendy, H H Duong, N J Fisch, E D Fredrickson, R K Fisher, R J Fonck, G Y Fu, V Goloborod'ko, N Gorelenkov, R J Hawryluk, R Heeter, W W Heidbrink, H W Herrmann, M Herrmann, D W Johnson, J Machuzak, R Majeski, K M McGuire, G McKee, S S Medley, H E Mynick, R Nazikian, M P Petrov, M H Redi, S Reznik, J Rogers, G Schilling, D A Spong, J D Strachan, B C Stratton, E Synakowski, G Taylor, S Wang, R B White, K L Wong, V Yavorski, and the TFTR Group

Subjects

Physics, Magnetic confinement fusion, Alpha particle, Electron, Plasma, Alpha (navigation), equipment and supplies, Condensed Matter Physics, Nuclear physics, Shear (sheet metal), Nuclear Energy and Engineering, Physics::Plasma Physics, Normal mode, Physics::Space Physics, Tokamak Fusion Test Reactor

Abstract

A summary is presented of recent alpha-particle experiments on the tokamak fusion test reactor. Alpha particles are generally well confined in MHD-quiescent discharges, and alpha heating of electrons has been observed. The theoretically predicted toroidicity-induced Alfv?n eigenmode has been seen in discharges of of alpha power, but only in plasmas with weak magnetic shear.

Published

1997

4. Ion and electron heating characteristics of magnetic reconnection in tokamak plasma merging experiments

Author

Y Ono, H Tanabe, T Yamada, M Inomoto, T Ii, S Inoue, K Gi, T Watanabe, M Gryaznevich, R Scannell, C Michael, and C Z Cheng

Subjects

Physics, Tokamak, Magnetic reconnection, Plasma, Condensed Matter Physics, Magnetic field, Ion, law.invention, Nanoflares, Current sheet, Nuclear Energy and Engineering, Physics::Plasma Physics, law, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Atomic physics, Joule heating

Abstract

Recently, the TS-3 and TS-4 tokamak merging experiments revealed significant plasma heating during magnetic reconnection. A key question is how and where ions and electrons are heated during magnetic reconnection. Two-dimensional measurements of ion and electron temperatures and plasma flow made clear that electrons are heated inside the current sheet mainly by the Ohmic heating and ions are heated in the downstream areas mainly by the reconnection outflows. The outflow kinetic energy is thermalized by the fast shock formation and viscous damping. The magnetic reconnection converts the reconnecting magnetic field energy mostly to the ion thermal energy in the outflow region whose size is much larger than the current sheet size for electron heating. The ion heating energy is proportional to the square of the reconnection magnetic field component . This scaling of reconnection heating indicates the significant ion heating effect of magnetic reconnection, which leads to a new high-field reconnection heating experiment for fusion plasmas.

Published

2012