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Bibliographic Details
Main Authors: Dunlea, Carl, Khalzov, Ivan
Format: Preprint
Published: 2019
Subjects:
Online Access:https://arxiv.org/abs/1907.13283
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author Dunlea, Carl
Khalzov, Ivan
author_facet Dunlea, Carl
Khalzov, Ivan
contents The DELiTE (Differential Equations on Linear Triangular Elements) framework was developed for spatial discretisation of partial differential equations on an unstructured triangular grid in axisymmetric geometry. The framework is based on discrete differential operators in matrix form, which are derived using linear finite elements and mimic some of the properties of their continuous counterparts. A single-fluid two-temperature MHD code is implemented in this framework. The inherent properties of the operators are used in the code to ensure global conservation of energy, particle count, toroidal flux, and angular momentum. The code was applied to study a novel experiment in which a compact torus (CT), produced with a magnetized Marshall gun, is magnetically levitated off an insulating wall and then magnetically compressed through the action of currents in the levitation/compression coils located outside the wall. We present numerical models for CT formation, levitation, and magnetic compression, and comparisons between simulated and experimental diagnostics.
format Preprint
id arxiv_https___arxiv_org_abs_1907_13283
institution arXiv
publishDate 2019
record_format arxiv
spellingShingle A globally conservative finite element MHD code and its application to the study of compact torus formation, levitation and magnetic compression
Dunlea, Carl
Khalzov, Ivan
Numerical Analysis
Plasma Physics
The DELiTE (Differential Equations on Linear Triangular Elements) framework was developed for spatial discretisation of partial differential equations on an unstructured triangular grid in axisymmetric geometry. The framework is based on discrete differential operators in matrix form, which are derived using linear finite elements and mimic some of the properties of their continuous counterparts. A single-fluid two-temperature MHD code is implemented in this framework. The inherent properties of the operators are used in the code to ensure global conservation of energy, particle count, toroidal flux, and angular momentum. The code was applied to study a novel experiment in which a compact torus (CT), produced with a magnetized Marshall gun, is magnetically levitated off an insulating wall and then magnetically compressed through the action of currents in the levitation/compression coils located outside the wall. We present numerical models for CT formation, levitation, and magnetic compression, and comparisons between simulated and experimental diagnostics.
title A globally conservative finite element MHD code and its application to the study of compact torus formation, levitation and magnetic compression
topic Numerical Analysis
Plasma Physics
url https://arxiv.org/abs/1907.13283