Efficient analysis of magnetic field line behavior in toroidal plasmas

TL;DR

This paper introduces a Fourier-Gaussian method for analyzing magnetic field line transitions in toroidal plasmas, significantly improving the efficiency and detail of divertor and disruption studies in fusion devices.

Contribution

The paper presents a novel Fourier-Gaussian analysis technique that enhances the extraction of transition information from magnetic field lines with fewer integrations.

Findings

More detailed transition information obtained with shorter integrations

Enhanced analysis of divertor properties and disruptions

Potential for improved fusion device design and safety

Abstract

The confinement of plasmas in tokamaks and stellarators depends on magnetic field lines lying in nested toroidal surfaces. The transition near the plasma edge away from the lines lying in magnetic surfaces defines properties of divertors. The transition in time defines properties of disruptions. Divertor design and disruption analyses require a detailed understanding of these transitions. The use of a Fourier transform coupled with a Gaussian window function allows far more information to be extracted about these transitions using far shorter field line integrations than can be obtained using traditional methods based on Poincar\'e plots. The physics of divertors and disruptions is reviewed to clarify why the type of information that can be gained from more efficient methods of analysis is of central importance to the fusion program based on magnetic confinement.