Centrifugal-mirror confinement with strong azimuthal magnetic field

T. Stoltzfus-Dueck; F. I. Parra

doi:10.1088/1361-6587/adfe8e

Centrifugal-mirror confinement with strong azimuthal magnetic field

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Abstract

One practical challenge for the centrifugal-mirror confinement concept is the large radial voltage necessary to drive supersonic azimuthal rotation. In principle, the addition of a strong azimuthal field could reduce the required voltage, since the simple azimuthal E × B drift would be replaced by more rapid azimuthal trapped-particle precession. Also, if the mirror ratio is large enough, newly ionized ions are accelerated to the necessary parallel velocities in their first bounce orbit, both confining and significantly heating them. Unfortunately, MHD analysis shows that the centrifugal-force-confining plasma current is purely azimuthal. This implies that only the axial magnetic field contributes to the confining magnetic pressure, severely limiting the usefulness of the azimuthal magnetic field in a beta-limited plasma scenario.

Original language	English (US)
Article number	095025
Journal	Plasma Physics and Controlled Fusion
Volume	67
Issue number	9
DOIs	https://doi.org/10.1088/1361-6587/adfe8e
State	Published - Sep 30 2025

All Science Journal Classification (ASJC) codes

Nuclear Energy and Engineering
Condensed Matter Physics

Keywords

Grad-Shafranov
MHD equilibrium
centrifugal mirror
trapped-particle precession

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10.1088/1361-6587/adfe8e

Cite this

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title = "Centrifugal-mirror confinement with strong azimuthal magnetic field",

abstract = "One practical challenge for the centrifugal-mirror confinement concept is the large radial voltage necessary to drive supersonic azimuthal rotation. In principle, the addition of a strong azimuthal field could reduce the required voltage, since the simple azimuthal E × B drift would be replaced by more rapid azimuthal trapped-particle precession. Also, if the mirror ratio is large enough, newly ionized ions are accelerated to the necessary parallel velocities in their first bounce orbit, both confining and significantly heating them. Unfortunately, MHD analysis shows that the centrifugal-force-confining plasma current is purely azimuthal. This implies that only the axial magnetic field contributes to the confining magnetic pressure, severely limiting the usefulness of the azimuthal magnetic field in a beta-limited plasma scenario.",

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TY - JOUR

T1 - Centrifugal-mirror confinement with strong azimuthal magnetic field

AU - Stoltzfus-Dueck, T.

AU - Parra, F. I.

PY - 2025/9/30

Y1 - 2025/9/30

N2 - One practical challenge for the centrifugal-mirror confinement concept is the large radial voltage necessary to drive supersonic azimuthal rotation. In principle, the addition of a strong azimuthal field could reduce the required voltage, since the simple azimuthal E × B drift would be replaced by more rapid azimuthal trapped-particle precession. Also, if the mirror ratio is large enough, newly ionized ions are accelerated to the necessary parallel velocities in their first bounce orbit, both confining and significantly heating them. Unfortunately, MHD analysis shows that the centrifugal-force-confining plasma current is purely azimuthal. This implies that only the axial magnetic field contributes to the confining magnetic pressure, severely limiting the usefulness of the azimuthal magnetic field in a beta-limited plasma scenario.

AB - One practical challenge for the centrifugal-mirror confinement concept is the large radial voltage necessary to drive supersonic azimuthal rotation. In principle, the addition of a strong azimuthal field could reduce the required voltage, since the simple azimuthal E × B drift would be replaced by more rapid azimuthal trapped-particle precession. Also, if the mirror ratio is large enough, newly ionized ions are accelerated to the necessary parallel velocities in their first bounce orbit, both confining and significantly heating them. Unfortunately, MHD analysis shows that the centrifugal-force-confining plasma current is purely azimuthal. This implies that only the axial magnetic field contributes to the confining magnetic pressure, severely limiting the usefulness of the azimuthal magnetic field in a beta-limited plasma scenario.

KW - Grad-Shafranov

KW - MHD equilibrium

KW - centrifugal mirror

KW - trapped-particle precession

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Centrifugal-mirror confinement with strong azimuthal magnetic field

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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