Theses Doctoral

Asymmetric Halo Current Rotation In Post-disruption Plasmas

Saperstein, Alex Ryan

Halo currents (HCs) in post-disruption plasmas can be large enough to exert significant electromagnetic loads on structures surrounding the plasma. These currents have axisymmetric and non-axisymmetric components, both of which pose threats to the vacuum vessel and other components. However, the non-axisymmetric forces can rotate, amplifying the displacements they cause when the rotation is close to the structures’ resonant frequencies. A new physically motivated scaling law has been developed that describes the rotation frequencies of these HCs and has been validated against measurements on HBT-EP, Alcator C-Mod, and other tokamaks.

This scaling law can describe the time-evolution of the asymmetric HC rotation throughout disruptions on HBT-EP as well as the time-averaged rotation on C-Mod. The scaling law can also be modified to include the edge safety factor at the onset of rotation (𝒒_π‘œπ‘›π‘ π‘’π‘‘), which significantly improves its validity when applied to machines like C-Mod, where 𝒒_π‘œπ‘›π‘ π‘’π‘‘ changes frequently.

The 𝒒_π‘œπ‘›π‘ π‘’π‘‘ dependence is explained by the relationship between the poloidal structure of the HC asymmetries and the MHD instabilities that drive them, which has been observed experimentally for the first time using a novel set of current sensing limiter tiles installed on HBT-EP. The 1/π‘ŽΒ² and 𝒒_π‘œπ‘›π‘ π‘’π‘‘-dependence of the rotation suggest that the HCs predominantly rotate poloidally. This remains consistent with the toroidal rotation observed on HBT-EP and other tokamaks through the β€œBarber Pole Illusion” and the direction of rotation’s dependence on the direction of 𝐼_𝑝. This scaling law is used to make projections for next generation tokamaks like ITER and SPARC, which predicts that rotation will be resonant on ITER. However, resonant effects can still be avoided if the duration of the disruption is kept short enough to prevent two rotations from being completed.

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More About This Work

Academic Units
Applied Physics and Applied Mathematics
Thesis Advisors
Mauel, Michael E.
Degree
Ph.D., Columbia University
Published Here
July 5, 2023