Your search keyword '"T.K. Ma"' showing total 2 results

1. The behavior of runaway current in massive gas injection fast shutdown plasmas in J-TEXT

Author

Li Gao, Zhoujun Yang, Y.B. Dong, Long Zeng, Qiming Hu, Y N Wei, Zhonghe Jiang, Xiang Jian, W. Yan, Bo Rao, R. H. Tong, J-Text Team, Ming Zhang, Silun Wang, G. Zhuang, Yichang Pan, T.K. Ma, Y. Tang, Z.J. Wang, Y.H. Luo, D.W. Huang, X.H. Wang, X.Q. Zhang, Yonghua Ding, Z.Y. Chen, and Jianchao Li

Subjects

Physics, Nuclear and High Energy Physics, Jet (fluid), Tokamak, Field line, Plasma, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, law.invention, Nuclear physics, law, Drag, 0103 physical sciences, Magnetohydrodynamic drive, Current (fluid), 010306 general physics, Beam (structure)

Abstract

Runaway currents following disruptions have an important effect on the first wall in current tokamaks and will be more severe in next generation tokamaks. The behavior of runaway currents in massive gas injection (MGI) induced disruptions have been investigated in the J-TEXT tokamak. The cold front induced by the gas jet penetrates helically along field lines, preferentially toward the high field side and stops at a location near the q = 2 surface before the disruption. When the cold front reaches the q = 2 surface it initiates magnetohydrodynamic activities and results in disruption. It is found that the MGI of He or Ne results in runaway free shutdown in a large range of gas injections. Mixture injection of He and Ar (90% He and 10%Ar) consistently results in runaway free shutdown. A moderate amount of Ar injection could produce significant runaway current. The maximum runaway energy in the runaway plateau is estimated using a simplified model which neglects the drag forces and other energy loss mechanisms. The maximum runaway energy increases with decreasing runaway current. Imaging of the runaway beam using a soft x-ray array during the runaway current plateau indicates that the runaway beam is located in the center of the plasma. Resonant magnetic perturbation (RMP) is applied to reduce the runaway current successfully during the disruption phase in a small scale tokamak, J-TEXT. When the runaway current builds up, the application of RMP cannot decouple the runaway beam due to the lower sensitivity of the energetic runaway electrons to the magnetic perturbation.

Published

2016

2. Enhancement of runaway production by resonant magnetic perturbation on J-TEXT

Author

Qiming Hu, D.W. Huang, J-Text Team, Valerie Izzo, D.H. Ding, G. Zhuang, Ming Zhang, W. Yan, T.K. Ma, Z.Y. Chen, S.C. Li, Y N Wei, Zhonghe Jiang, Bo Rao, R. H. Tong, Silun Wang, Zhoujun Yang, Yichang Pan, and Z.J. Wang

Subjects

Physics, Nuclear and High Energy Physics, Magnetic perturbation, Mechanics, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Plasma current, Nuclear physics, Safe operation, Runaway electrons, 0103 physical sciences, Current (fluid), 010306 general physics, Large size

Abstract

The suppression of runaways following disruptions is key for the safe operation of ITER. The massive gas injection (MGI) has been developed to mitigate heat loads, electromagnetic forces and runaway electrons (REs) during disruptions. However, MGI may not completely prevent the generation of REs during disruptions on ITER. Resonant magnetic perturbation (RMP) has been applied to suppress runaway generation during disruptions on several machines. It was found that strong RMP results in the enhancement of runaway production instead of runaway suppression on J-TEXT. The runaway current was about 50% pre-disruption plasma current in argon induced reference disruptions. With moderate RMP, the runway current decreased to below 30% pre-disruption plasma current. The runaway current plateaus reach 80% of the pre-disruptive current when strong RMP was applied. Strong RMP may induce large size magnetic islands that could confine more runaway seed during disruptions. This has important implications for runaway suppression on large machines.

Published

2016