Full Paper
IAEA-CN77
Contents  Return  Previous Page  Next Page  Index


Return To: Session THP2 - MHD, Energetic Particles & Current
Prev Page: (THP2/12) Theory and MHD Simulation of Fuelling Process
Next Page: (THP2/14) Three Dimensional Ideal MHD Stability Analysis in


(THP2/13) Dynamics of Relaxation Phenomena in Spherical Tokamak

T. Hayashi, N. Mizuguchi, H. Miura, T. Sato
 
1) National Institute for Fusion Science, Toki, Japan

Abstract.  Three-dimensional magnetohydrodynamic (MHD) simulations are executed to clarify the physical mechanisms of MHD relaxation activities, specifically the Internal Reconnection Event (IRE), which are observed in the spherical tokamak experiments. For a case of an initial equilibrium with q(0) less than one, tunnel-like plasma jet flow is formed by the occurrence of the external magnetic reconnection accompanying the growth of localized deformation of torus. When initial q(0) is slightly greater than one, upon increase of beta, multiple mode number of finer-scale ballooning type instabilities is triggered, where the typical toroidal mode number n is 11. In the nonlinear stage, the surface of the torus is deformed due to growth of those medium-n modes, and a part of heat energy is lost into the external region through occurrence of external reconnection. Interestingly, low n modes, particularly n=2, are enhanced presumably by nonlinear coupling among the unstable medium-n modes, and the n=2 type deformation of the torus becomes dominant in the later stage.

Read the full paper in PDF format.

IAEA 2001