Salvato in:
Dettagli Bibliografici
Autori principali: Tecchiolli, Z., Coelho, A. J., Loizu, J., De Lucca, B., Ricci, P.
Natura: Preprint
Pubblicazione: 2025
Soggetti:
Accesso online:https://arxiv.org/abs/2508.04881
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866913978744045568
author Tecchiolli, Z.
Coelho, A. J.
Loizu, J.
De Lucca, B.
Ricci, P.
author_facet Tecchiolli, Z.
Coelho, A. J.
Loizu, J.
De Lucca, B.
Ricci, P.
contents The effect of magnetic shear on ballooning-driven plasma edge turbulence is studied through nonlinear simulations complemented by linear numerical and analytical investigations. Nonlinear, 3D, global, flux-driven simulations using the GBS code show that the scale separation between radial, x, and poloidal, y, size of turbulent eddies, kx << ky , considered by Ricci et al. (2008) and extensively used to predict pressure gradient lengths, SOL width, particle and heat fluxes, is observed with high magnetic shear. In contrast, for low magnetic shear, kx ~ ky is observed, with fluctuation properties resembling those shown by recent low-shear stellarator simulations reported in Coelho et al. (2024a). Global linear investigations of the ballooning mode qualitatively captures the transition in mode structure with varying magnetic shear, showing that kx << ky is achieved with sufficiently strong poloidal mode coupling enhanced by increasing magnetic shear, resistivity, toroidal mode number, and equilibrium gradient scale length. This is confirmed by an analytical study considering a dominant poloidal mode and its sidebands, which highlights that the poloidal mode structure is determined by curvature and k parallel effects
format Preprint
id arxiv_https___arxiv_org_abs_2508_04881
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Magnetic shear effects on ballooning turbulence in the boundary of fusion devices
Tecchiolli, Z.
Coelho, A. J.
Loizu, J.
De Lucca, B.
Ricci, P.
Plasma Physics
The effect of magnetic shear on ballooning-driven plasma edge turbulence is studied through nonlinear simulations complemented by linear numerical and analytical investigations. Nonlinear, 3D, global, flux-driven simulations using the GBS code show that the scale separation between radial, x, and poloidal, y, size of turbulent eddies, kx << ky , considered by Ricci et al. (2008) and extensively used to predict pressure gradient lengths, SOL width, particle and heat fluxes, is observed with high magnetic shear. In contrast, for low magnetic shear, kx ~ ky is observed, with fluctuation properties resembling those shown by recent low-shear stellarator simulations reported in Coelho et al. (2024a). Global linear investigations of the ballooning mode qualitatively captures the transition in mode structure with varying magnetic shear, showing that kx << ky is achieved with sufficiently strong poloidal mode coupling enhanced by increasing magnetic shear, resistivity, toroidal mode number, and equilibrium gradient scale length. This is confirmed by an analytical study considering a dominant poloidal mode and its sidebands, which highlights that the poloidal mode structure is determined by curvature and k parallel effects
title Magnetic shear effects on ballooning turbulence in the boundary of fusion devices
topic Plasma Physics
url https://arxiv.org/abs/2508.04881