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Main Authors: Miller, Tal, Gudinetsky, Eli, Be'ery, Ilan, Barth, Ido
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.06298
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author Miller, Tal
Gudinetsky, Eli
Be'ery, Ilan
Barth, Ido
author_facet Miller, Tal
Gudinetsky, Eli
Be'ery, Ilan
Barth, Ido
contents Axial plugging is a critical challenge for fusion in open-ended magnetic confinement systems. Multi-mirror systems, consisting of a series of axially aligned magnetic mirrors, aim to enhance axial confinement by increasing the effective diffusion coefficient; however, additional plugging is required to meet the Lawson criterion. In [T. Miller et al., Phys. Plasmas 30, 072510 (2023)], it was found that applying a traveling and rotating electric field in multi-mirror machines can significantly suppress axial loss due to a selectivity effect induced by the Doppler shift of the ion cyclotron resonance. However, this method is energetically expensive and vulnerable to plasma screening effects. Here, we propose using a traveling, rotating magnetic field that can achieve comparable plugging effectiveness while offering better penetration and lower energy costs. Two limiting scenarios, with and without an induced electric field, were considered. The confinement enhancement is calculated using a semi-kinetic rate equation model, in which the flux coefficients are determined from single-particle simulations. While both scenarios exhibit significant confinement enhancement, the scenario without an induced electric field is much more energetically efficient, as it relies on phase-space mixing rather than on energy deposition in the escaping particles. The decoupling of confinement from plasma collisionality enables fusion conditions in the central cell while allowing affordable and efficient confinement enhancement in the multi-mirror sections.
format Preprint
id arxiv_https___arxiv_org_abs_2603_06298
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Plugging of multi-mirror machines by a traveling rotating magnetic field
Miller, Tal
Gudinetsky, Eli
Be'ery, Ilan
Barth, Ido
Plasma Physics
Axial plugging is a critical challenge for fusion in open-ended magnetic confinement systems. Multi-mirror systems, consisting of a series of axially aligned magnetic mirrors, aim to enhance axial confinement by increasing the effective diffusion coefficient; however, additional plugging is required to meet the Lawson criterion. In [T. Miller et al., Phys. Plasmas 30, 072510 (2023)], it was found that applying a traveling and rotating electric field in multi-mirror machines can significantly suppress axial loss due to a selectivity effect induced by the Doppler shift of the ion cyclotron resonance. However, this method is energetically expensive and vulnerable to plasma screening effects. Here, we propose using a traveling, rotating magnetic field that can achieve comparable plugging effectiveness while offering better penetration and lower energy costs. Two limiting scenarios, with and without an induced electric field, were considered. The confinement enhancement is calculated using a semi-kinetic rate equation model, in which the flux coefficients are determined from single-particle simulations. While both scenarios exhibit significant confinement enhancement, the scenario without an induced electric field is much more energetically efficient, as it relies on phase-space mixing rather than on energy deposition in the escaping particles. The decoupling of confinement from plasma collisionality enables fusion conditions in the central cell while allowing affordable and efficient confinement enhancement in the multi-mirror sections.
title Plugging of multi-mirror machines by a traveling rotating magnetic field
topic Plasma Physics
url https://arxiv.org/abs/2603.06298