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Autori principali: Jäderberg, Jan, Bendtz, Katarina, Lindvall, Kristoffer, Scheffel, Jan, Holmberg, Rickard, Niva, Per, Dahlbäck, Robin, Lundberg, Johan
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2310.16711
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author Jäderberg, Jan
Bendtz, Katarina
Lindvall, Kristoffer
Scheffel, Jan
Holmberg, Rickard
Lindvall, Kristoffer
Niva, Per
Dahlbäck, Robin
Lundberg, Johan
author_facet Jäderberg, Jan
Bendtz, Katarina
Lindvall, Kristoffer
Scheffel, Jan
Holmberg, Rickard
Lindvall, Kristoffer
Niva, Per
Dahlbäck, Robin
Lundberg, Johan
contents A new magnetic mirror-cusp concept is described - the Novatron - with the potential to confine compact and stable fusion plasmas. Traditionally, the major challenges for open field line designs include MHD interchange modes, drift cyclotron loss-cone (DCLC) modes, neoclassical transport, and axial losses of particles and energy. The novel magnetic field configuration features favorable curvature throughout the plasma region, suppressing interchange modes. Moreover, the Novatron is designed to be self-stabilized against DCLC modes by allowing for a large plasma to Larmor radius ratio. The vacuum magnetic field geometry is axisymmetric, mitigating neoclassical transport. The Novatron features a high mirror ratio, providing strong magnetic confinement and suppressed axial losses. This paper describes the fundamental magnetic field topology and outlines the design of the magnet system. MHD interchange stability of anisotropic low-\b{eta} equilibria is demonstrated by derivation of two novel criteria, based on anisotropic ideal MHD and the Chew-Goldberger-Low model, and numerical computation in Novatron geometry. The Novatron design is also placed into a historic context by summarizing challenges faced by both previous and more current mirror/cusp concepts.
format Preprint
id arxiv_https___arxiv_org_abs_2310_16711
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Introducing the Novatron, a novel mirror fusion concept
Jäderberg, Jan
Bendtz, Katarina
Lindvall, Kristoffer
Scheffel, Jan
Holmberg, Rickard
Lindvall, Kristoffer
Niva, Per
Dahlbäck, Robin
Lundberg, Johan
Plasma Physics
A new magnetic mirror-cusp concept is described - the Novatron - with the potential to confine compact and stable fusion plasmas. Traditionally, the major challenges for open field line designs include MHD interchange modes, drift cyclotron loss-cone (DCLC) modes, neoclassical transport, and axial losses of particles and energy. The novel magnetic field configuration features favorable curvature throughout the plasma region, suppressing interchange modes. Moreover, the Novatron is designed to be self-stabilized against DCLC modes by allowing for a large plasma to Larmor radius ratio. The vacuum magnetic field geometry is axisymmetric, mitigating neoclassical transport. The Novatron features a high mirror ratio, providing strong magnetic confinement and suppressed axial losses. This paper describes the fundamental magnetic field topology and outlines the design of the magnet system. MHD interchange stability of anisotropic low-\b{eta} equilibria is demonstrated by derivation of two novel criteria, based on anisotropic ideal MHD and the Chew-Goldberger-Low model, and numerical computation in Novatron geometry. The Novatron design is also placed into a historic context by summarizing challenges faced by both previous and more current mirror/cusp concepts.
title Introducing the Novatron, a novel mirror fusion concept
topic Plasma Physics
url https://arxiv.org/abs/2310.16711