Modelling of spatial structure of divertor footprints caused by edge-localized modes mitigated by magnetic perturbations

TL;DR

This paper develops a theory explaining how magnetic perturbations modify the spatial structure of ELM footprints on divertors, supported by simulations showing footprint patterns consistent with the theory.

Contribution

The paper introduces a new theoretical framework linking ELM mitigation effects to changes in magnetic field line structures, validated through detailed JOREK simulations.

Findings

Mitigated ELMs show footprint structures aligned with magnetic perturbations.

Simulations reveal high-n rotating footprint patterns during ELMs.

The theory explains the spatial redistribution of ELM energy loads.

Abstract

Resonant magnetic perturbations (RMPs) can mitigate the edge-localized modes (ELMs), i.e. cause a change of the ELM character towards smaller energy loss and higher frequency. During mitigation a change of the spatial structure of ELM loads on divertor was observed on DIII-D and MAST: the power is deposited predominantly in the footprint structures formed by the magnetic perturbation. In the present contribution we develop a theory explaining this effect, based on the idea that part of the ELM loss is caused by parallel transport in the homoclinic tangle formed by the magnetic perturbation of the ELM. The modified tangle resulting from the combination of the ELM perturbation and the applied RMP has the expected property of bringing open field lines in the same areas as the tangle from the RMP alone. We show that this explanation is consistent with features of the mitigated ELMs on MAST. We in addition validated our theory by an analysis of simulations of mitigated ELMs using the code JOREK. We produced detailed laminar plots of field lines on the divertor in the JOREK runs with an ELM, an applied RMP, and an ELM mitigated by the presence of the RMP. The results for an ELM clearly show a high-n rotating footprint structure appearing during the nonlinear stage of the ELM, which is not present in the early stage of the ELM. The results for a n=2 RMP from the ELM control coils show the expected n=2 footprint structure. The results for the mitigated ELM show a similar structure, modulated by a higher n perturbation of the ELM, consistent with our theory.