Details

Autor(en) / Beteiligte

• Huang, Y.
• Chen, Z.Y.
• Hu, Qiming
• Yu, Q.
• Jiang, Z.H.
• Wei, Y.N.
• Su, Pengjuan
• Shen, Chengshuo
• Guo, Daojing
• Yang, Z.J.
• Pan, X.M.
• Huang, Mingxiang
• Cai, Qinxue
• Wang, Tong
• Lin, Z.F.
• Tong, R.H.
• Yan, W.
• Chen, Z.P.
• Ding, Y.H.
• Liang, Y.

Titel

Study of MHD mode and cooling process during disruptions triggered by impurities injection in J-TEXT

Ist Teil von

• Nuclear fusion, 2018-12, Vol.58 (12), p.126024

Ort / Verlag

United States: IOP Publishing

Erscheinungsjahr

2018

Link zum Volltext

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• The injection of a large amount of impurities is one of the possible ways of mitigating disruption in large-scale tokamaks. The deposition of impurities at the center of the plasma is the key to the radiation of plasma energy and suppression of runaway. The interaction of the gas jet with the rational surfaces has been studied by scanning the plasma current. The experimental results show that the injection of a massive amount of argon can cool the plasma from the edge to the core region, and the cooling process is accompanied by different magnetohydrodynamic (MHD) modes when the gas jet reaches the corresponding rational surfaces. It is observed that with different edge safety factors and electron density, gas injection can induce different poloidal modes at first. Then, the poloidal mode traverses to lower m (where m is the poloidal mode number) MHD activities until a 2/1 mode is initiated and a thermal quench is started. The experimental results show that the penetration of a gas jet across the rational surfaces is faster in the plasmas with pre-existing large 2/1 tearing modes, which indicates that the 2/1 mode plays an important role in the penetration process. Disruptions triggered by supersonic molecular beam injection display a slower cooling process compared with massive gas injection, which can be divided into four stages. The dominant poloidal mode transition from m  =  3 to m  =  2 is associated with electron temperature recovery.