Effect of resonant magnetic perturbations including toroidal sidebands on magnetic footprints and fast ion losses in HL-2M

Author:

Hao G.Z.ORCID,Dong G.Q.ORCID,Liu Y.Q.ORCID,Xu Y.H.,Zhao Y.F.ORCID,Wang S.ORCID,He H.D.,Xue M.,Li Z.J.,Li J.X.,Li C.Y.,Wang L.,Xu J.Q.ORCID,Chen W.ORCID,Cai L.J.,Zhong W.L.,Xu M.,Duan X.R.

Abstract

Abstract Externally applied resonant magnetic perturbations (RMPs), generated by magnetic coils located outside the plasma (referred to as RMP coils), provide an effective way to control the edge localized mode (ELM) in tokamak devices. Due to the discrete nature of the toroidal distribution of these window-frame coils, toroidal sidebands always exist together with the fundamental harmonics designed for ELM control. In this work, the MARS-F code (Liu et al 2000 Phys. Plasmas 7 3681) is applied to investigate the detailed features of the RMP spectra considering both the dominant harmonic (n = 2) and the associated sideband (n = 6), and the impact of the combined fields on magnetic footprints as well as on the fast ion losses for a reference double-null scenario in the HL-2M device. It is found that the sum of the n = 2 and n = 6 RMP fields splits the footprint and widens the footprint area, as compared to the single-n (n = 2) harmonic case. The resistive plasma response breaks the up–down symmetry of the footprint pattern on the outer divertor plates, which is otherwise symmetric assuming vacuum RMP fields. Considering fast ion losses, a threshold value exists for the initially launched radial position of test particles, as well as for the RMP coil current, before the loss occurs. When the threshold criterion is satisfied, the combined n = 2 and n = 6 RMP fields enhance the fast ion loss rate by 20 % , as compared to that of the n = 2 component alone. These results illustrate the important role of the sideband of RMP fields on the magnetic footprints and fast ion losses in tokamak plasmas.

Funder

US DoE Office of Science

National Magnetic Confinement Fusion Energy R&D Program

Publisher

IOP Publishing

Subject

Condensed Matter Physics,Nuclear and High Energy Physics

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