The 3D magnetic topology and plasma dynamics in open stochastic magnetic field lines

The thermal quench triggered by locked modes is known to be mainly due to open stochastic magnetic field lines connected to the wall boundary. It is essential to understand the 3D structure of open stochastic field lines since it determines the overall plasma dynamics in the system. In this study, we analyze the 3D magnetic topology for two key concepts, the connection length L-c and the effective magnetic mirror ratio M eff, and present a comprehensive picture of electron and ion dynamics related to the magnetic topology. The connection length determines the 3D structure of the ambipolar potential, and a sharp potential drop across distinct L-c regions induces the E x B transport and mixing across the field line. The confinement of electrons and ions along the field line is determined by the ambipolar potential and M eff configuration. Electron and ion temperatures in magnetic hills ( M eff < 1) are lower than in magnetic wells ( M eff > 1) because particles in magnetic hills are more likely to escape toward the wall boundary along the field line. The mixing between the magnetic wells and hills by E x B and magnetic drift motions results in collisionless detrapping of electrons and ions, which reduces their temperature efficiently. Numerical simulations of two different magnetic configurations demonstrate the importance of the collisionless detrapping mechanism, which could be the main cause of plasma temperature drop during the thermal quench.

Automated summary

By analyzing the 3D magnetic topology of the connection length and effective magnetic mirror ratio, this study provides a comprehensive understanding of electron and ion dynamics related to the magnetic topology. The connection length and effective magnetic mirror ratio determine the motion and mixing of electrons and ions in the magnetic field, leading to a reduction in plasma temperature.