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Auteurs principaux: Trinczek, Silvia, Parra, Felix I., Catto, Peter J.
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2504.03016
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author Trinczek, Silvia
Parra, Felix I.
Catto, Peter J.
author_facet Trinczek, Silvia
Parra, Felix I.
Catto, Peter J.
contents Standard approaches to neoclassical theory do not extend into regions of strong gradients in tokamaks such as the pedestal and internal transport barriers. Here, we calculate the modifications to neoclassical electron physics inside strong gradient regions of large aspect ratio tokamaks. We show that these modifications are due to the different ion flow and the strong poloidal variation of the potential. We also provide a physical interpretation of the mechanisms that drive poloidal asymmetries and hence a poloidal electric field. We apply our model to two specific example cases of pedestal profiles, calculating the neoclassical electron flux and the bootstrap current. We find that depending on the ion flow, weak gradient neoclassical theory overestimates or underestimates the neoclassical electron transport and the bootstrap current in regions with strong gradients. We show that the determination of the mean parallel flow is more complex than in weak gradient neoclassical theory. For vanishing turbulence, we can determine the radial electric field for a given flow profile in the pedestal.
format Preprint
id arxiv_https___arxiv_org_abs_2504_03016
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Strong gradient effects on neoclassical electron transport and the bootstrap current
Trinczek, Silvia
Parra, Felix I.
Catto, Peter J.
Plasma Physics
Standard approaches to neoclassical theory do not extend into regions of strong gradients in tokamaks such as the pedestal and internal transport barriers. Here, we calculate the modifications to neoclassical electron physics inside strong gradient regions of large aspect ratio tokamaks. We show that these modifications are due to the different ion flow and the strong poloidal variation of the potential. We also provide a physical interpretation of the mechanisms that drive poloidal asymmetries and hence a poloidal electric field. We apply our model to two specific example cases of pedestal profiles, calculating the neoclassical electron flux and the bootstrap current. We find that depending on the ion flow, weak gradient neoclassical theory overestimates or underestimates the neoclassical electron transport and the bootstrap current in regions with strong gradients. We show that the determination of the mean parallel flow is more complex than in weak gradient neoclassical theory. For vanishing turbulence, we can determine the radial electric field for a given flow profile in the pedestal.
title Strong gradient effects on neoclassical electron transport and the bootstrap current
topic Plasma Physics
url https://arxiv.org/abs/2504.03016