Strong gradient effects on neoclassical electron transport and the bootstrap current in large aspect ratio tokamaks

Journal of Plasma Physics Cambridge University Press (CUP) 91:4 (2025) e97

Authors:

Silvia Trinczek, Felix I Parra, Peter J Catto

Abstract:

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 in the banana regime. 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.

Cosmic-ray transport in inhomogeneous media

(2025)

Authors:

Robert J Ewart, Patrick Reichherzer, Shuzhe Ren, Stephen Majeski, Francesco Mori, Michael L Nastac, Archie FA Bott, Matthew W Kunz, Alexander A Schekochihin

Angular-momentum pairs in spherical systems: applications to the Galactic centre

(2025)

Authors:

Taras Panamarev, Yonadav Barry Ginat, Bence Kocsis

Thermodynamics and collisionality in firehose-susceptible high-$β$ plasmas

(2025)

Authors:

AFA Bott, MW Kunz, E Quataert, J Squire, L Arzamasskiy

The gyrokinetic field invariant and electromagnetic temperature-gradient instabilities in ‘good-curvature’ plasmas

Journal of Plasma Physics Cambridge University Press 91:4 (2025) E95

Authors:

PG Ivanov, P Luhadiya, T Adkins, AA Schekochihin

Abstract:

Curvature-driven instabilities are ubiquitous in magnetised fusion plasmas. By analysing the conservation laws of the gyrokinetic system of equations, we demonstrate that the well-known spatial localisation of these instabilities to regions of ‘bad magnetic curvature’ can be explained using the conservation law for a sign-indefinite quadratic quantity that we call the gyrokinetic field invariant. Its evolution equation allows us to define the local effective magnetic curvature whose sign demarcates the regions of ‘good’ and ‘bad’ curvature, which, under some additional simplifying assumptions, can be shown to correspond to the inboard (high-field) and outboard (low-field) sides of a tokamak plasma, respectively. We find that, given some reasonable assumptions, electrostatic curvature-driven modes are always localised to the regions of bad magnetic curvature, regardless of the specific character of the instability. More importantly, we also deduce that any mode that is unstable in the region of good magnetic curvature must be electromagnetic in nature. As a concrete example, we present the magnetic-drift mode, a novel good-curvature electromagnetic instability, and compare its properties with the well-known electron-temperature-gradient instability. Finally, we discuss the relevance of the magnetic drift mode for high- fusion plasmas, and in particular its relationship with microtearing modes.