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Main Authors: Gudinetsky, Eli, Miller, Tal, Be'ery, Ilan, Barth, Ido
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.18687
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author Gudinetsky, Eli
Miller, Tal
Be'ery, Ilan
Barth, Ido
author_facet Gudinetsky, Eli
Miller, Tal
Be'ery, Ilan
Barth, Ido
contents Magnetic confinement fusion reactors produce ash particles that must be removed for efficient operation. It is suggested to use autoresonance (a continuous phase-locking between anharmonic motion and a chirped drive) to remove the ash particles from a magnetic mirror, the simplest magnetic confinement configuration. An analogy to the driven pendulum is established via the guiding center approximation. The full 3D dynamics is simulated for $α$ particles (the byproduct of DT fusion) in agreement with the approximated 1D model. Monte Carlo simulations sampling the phase space of initial conditions are used to quantify the efficiency of the method. The DT fuel particles are out of the bandwidth of the chirped drive and, therefore, stay in the mirror for ongoing fusion. The method is also applicable for advanced, aneutronic reactors, such as p-$^{11}$B.
format Preprint
id arxiv_https___arxiv_org_abs_2402_18687
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Autoresonant Removal of Fusion Products in Mirror Machines
Gudinetsky, Eli
Miller, Tal
Be'ery, Ilan
Barth, Ido
Plasma Physics
Magnetic confinement fusion reactors produce ash particles that must be removed for efficient operation. It is suggested to use autoresonance (a continuous phase-locking between anharmonic motion and a chirped drive) to remove the ash particles from a magnetic mirror, the simplest magnetic confinement configuration. An analogy to the driven pendulum is established via the guiding center approximation. The full 3D dynamics is simulated for $α$ particles (the byproduct of DT fusion) in agreement with the approximated 1D model. Monte Carlo simulations sampling the phase space of initial conditions are used to quantify the efficiency of the method. The DT fuel particles are out of the bandwidth of the chirped drive and, therefore, stay in the mirror for ongoing fusion. The method is also applicable for advanced, aneutronic reactors, such as p-$^{11}$B.
title Autoresonant Removal of Fusion Products in Mirror Machines
topic Plasma Physics
url https://arxiv.org/abs/2402.18687