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Autori principali: Frerichs, Heinke, Boeyaert, Dieter, Feng, Yuhe, Reiter, Detlev
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2604.11497
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author Frerichs, Heinke
Boeyaert, Dieter
Feng, Yuhe
Reiter, Detlev
author_facet Frerichs, Heinke
Boeyaert, Dieter
Feng, Yuhe
Reiter, Detlev
contents The divertor in a magnetic confinement fusion reactor is an essential component for power dissipation and particle removal. The FIREFLY package for rapid evaluation of divertor designs is presented as an extension of the FLARE code for field line reconstruction from a flux tube mesh. First, divertor loads are approximated with a simplified heat transport model. Neutralized particles are then sampled from the resulting load distribution, and the EIRENE code is used to track molecules and atoms in a plasma background while accounting for dissociation, charge exchange and ionization. Particles are removed on pumping surfaces in order to estimate the exhaust efficiency for a given divertor geometry. Optimization of the divertor geometry for more efficient particle exhaust is explored by using W7-X as an example, and the sensitivity to model parameters for the plasma background in the proxy calculations is evaluated.
format Preprint
id arxiv_https___arxiv_org_abs_2604_11497
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle FIREFLY: heat load and particle exhaust approximations for rapid evaluation of divertor designs
Frerichs, Heinke
Boeyaert, Dieter
Feng, Yuhe
Reiter, Detlev
Plasma Physics
The divertor in a magnetic confinement fusion reactor is an essential component for power dissipation and particle removal. The FIREFLY package for rapid evaluation of divertor designs is presented as an extension of the FLARE code for field line reconstruction from a flux tube mesh. First, divertor loads are approximated with a simplified heat transport model. Neutralized particles are then sampled from the resulting load distribution, and the EIRENE code is used to track molecules and atoms in a plasma background while accounting for dissociation, charge exchange and ionization. Particles are removed on pumping surfaces in order to estimate the exhaust efficiency for a given divertor geometry. Optimization of the divertor geometry for more efficient particle exhaust is explored by using W7-X as an example, and the sensitivity to model parameters for the plasma background in the proxy calculations is evaluated.
title FIREFLY: heat load and particle exhaust approximations for rapid evaluation of divertor designs
topic Plasma Physics
url https://arxiv.org/abs/2604.11497