摘要
In this work, physical models of neoclassical tearing modes (NTMs) including bootstrap current and multiple modulated electron cyclotron current drive model are applied. Based on the specific physical problems during the suppression of NTMs by driven current, this work compares the efficiency of continuous and modulated driven currents, and simulates the physical processes of multiple modulated driven currents on suppressing rotating magnetic island. It is found that when island rotates along the poloidal direction, the suppression ability of continuous driven current can be massively reduced due to current deposition outside the island separatrix and reverse deposition direction at the X point, which can be avoided by current drive modulation. Multiple current drive has a better suppressing effect than single current drive. This work gives realistic numerical simulations by optimizing the model and parameters based on the experiments, which could provide references for successful suppression of NTMs in future advanced tokamak such as international thermonuclear experimental reactor.
In this work, physical models of neoclassical tearing modes (NTMs) including bootstrap current and multiple modulated electron cyclotron current drive model are applied. Based on the specific physical problems during the suppression of NTMs by driven current, this work compares the efficiency of continuous and modulated driven currents, and simulates the physical processes of multiple modulated driven currents on suppressing rotating magnetic island. It is found that when island rotates along the poloidal direction, the suppression ability of continuous driven current can be massively reduced due to current deposition outside the island separatrix and reverse deposition direction at the X point, which can be avoided by current drive modulation. Multiple current drive has a better suppressing effect than single current drive. This work gives realistic numerical simulations by optimizing the model and parameters based on the experiments, which could provide references for successful suppression of NTMs in future advanced tokamak such as international thermonuclear experimental reactor.
作者
Long CHEN
Jinyuan LIU
Ping DUAN
Guangrui LIU
Xingyu BIAN
陈龙;刘金远;段萍;刘广睿;边兴宇(Department of Physics,Dalian Maritime University;Transportation Engineering Postdoctoral Research Station,Dalian Maritime University;School of Physics and Optoelectronic Engineering,Dalian University of Technology)
基金
supported by National Natural Science Foundation of China(Grand Nos.11605021,11375039 and 11275034)
Natural Science Foundation of Liaoning Province(Grand No.201601074)
supported by'the Fundamental Research Funds for the Central Universities'(Grand Nos.3132016128 and 3132014328)
