<RESEARCH REPORT>Plasma Simulation by Macroscale, Electromagnetic Particle Code and its Application to Current-Drive by Relativistic Electron Beam Injection
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概要
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A new implicit macroscale electromagnetic particle simulation code (MARC) which allows a large scale length and a time step in multi-dimensions is described. Finite mass electrons and ions are used with relativistic version of the equation of motion. The electromagnetic fields are solved by using a complete set of Maxwell equations. For time integration of the field equations, a decentered (backward) finite differencing scheme is employed with the predictor-corrector method for small noise and super-stability. It is shown both in analytical and numerical ways that the present scheme efficiently suppresses high frequency electrostatic and electromagnetic waves in a plasma, and that it accurately reproduces low frequency waves such as ion acoustic waves, Alfven waves and fast magnetosonic waves. The present numerical scheme has currently been coded in three dimensions for application to a new tokamak current-drive method by means of relativistic electron beam injection. Some remarks of the proper macroscale code application is presented in this paper.
- 核融合科学研究所の論文
著者
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Tanaka Motohiko
Institute For Fusion Theory Hiroshima University
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Sato Tetsuya
Institute for Fusion Theory, Hiroshima University
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Sato Tetsuya
Institute For Fusion Theory Hiroshima University
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