T. TAKIZUKA. Development of the PARASOL Code and Full Particle Simulation of Tokamak Plasma with an Open-Field SOL-Divertor Region Using PARASOL[J]. Plasma Science and Technology, 2011, 13(3): 316-325.
Citation:
T. TAKIZUKA. Development of the PARASOL Code and Full Particle Simulation of Tokamak Plasma with an Open-Field SOL-Divertor Region Using PARASOL[J]. Plasma Science and Technology, 2011, 13(3): 316-325.
T. TAKIZUKA. Development of the PARASOL Code and Full Particle Simulation of Tokamak Plasma with an Open-Field SOL-Divertor Region Using PARASOL[J]. Plasma Science and Technology, 2011, 13(3): 316-325.
Citation:
T. TAKIZUKA. Development of the PARASOL Code and Full Particle Simulation of Tokamak Plasma with an Open-Field SOL-Divertor Region Using PARASOL[J]. Plasma Science and Technology, 2011, 13(3): 316-325.
Japan Atomic Energy Agency, Naka Fusion Institute, Naka 311-0193, Japan
Funds: supported partly by the JSPS-CAS Core-University Program in the ¯eld of `Plasma and Nuclear Fusion', and partly by the Grant-in-Aid for Scienti¯c Research of Japan Society for the Promotion of Science
The PARASOL code and the simulation by using PARASOL are introduced briefly. The PARASOL code with particle-in-cell (PIC) method and binary collision model was developed in JAERI and JAEA. Simulations using PARASOL code were carried out in order to investigate the power and particle control with diveror system in fusion reactors. The one-dimensional (1D) version of PARASOL was adopted to investigate the Bohm criterion, the supersonic flow, the SOL heat conduction, and so on. The heat propagation due to edge localized mode (ELM) was studied with the 1D-dynamic PARASOL. The two-dimensional version of PARASOL for the whole tokamak plasma including scrape-off-layer (SOL)-divertor region was useful for simulating the SOL °ow pattern, the electric ¯eld formation etc. Based on PARASOL simulation results, improved physics modeling for the °uid simulation was built up.
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