Global gyrokinetic analysis of Wendelstein 7-X discharge: unveiling the importance of trapped-electron-mode and electron-temperature-gradient turbulence

Wendelstein 7-X Team; Felix Wilms; Alejandro Bañón Navarro; Thomas Windisch; Sergey Bozhenkov; Felix Warmer; Golo Fuchert; Oliver Ford; Daihong Zhang; Torsten Stange; Frank Jenko

doi:10.1088/1741-4326/ad6675

Global gyrokinetic analysis of Wendelstein 7-X discharge: unveiling the importance of trapped-electron-mode and electron-temperature-gradient turbulence

Wendelstein 7-X Team, Felix Wilms (Corresponding author), Alejandro Bañón Navarro, Thomas Windisch, Sergey Bozhenkov, Felix Warmer, Golo Fuchert, Oliver Ford, Daihong Zhang, Torsten Stange, Frank Jenko

Science and Technology of Nuclear Fusion

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

We present the first nonlinear, gyrokinetic, radially global simulation of a discharge of the Wendelstein 7-X-like stellarator, including kinetic electrons, an equilibrium radial electric field, as well as electromagnetic and collisional effects. By comparison against flux-tube and full-flux-surface simulations, we assess the impact of the equilibrium ExB-flow and flow shear on the stabilisation of turbulence. In contrast to the existing literature, we further provide substantial evidence for the turbulent electron heat flux being driven by trapped-electron-mode and electron-temperature-gradient turbulence in the core of the plasma. The former manifests as a hybrid together with ion-temperature-gradient turbulence and is primarily driven by the finite electron temperature gradient, which has largely been neglected in nonlinear stellarator simulations presented in the existing literature.

Original language	English
Article number	096040
Number of pages	15
Journal	Nuclear Fusion
Volume	64
Issue number	9
DOIs	https://doi.org/10.1088/1741-4326/ad6675
Publication status	Published - Sept 2024

Keywords

gyrokinetic simulations
stellarator turbulence
Wendelstein 7-X

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10.1088/1741-4326/ad6675

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Wendelstein 7-X Team, Wilms, F., Bañón Navarro, A., Windisch, T., Bozhenkov, S., Warmer, F., Fuchert, G., Ford, O., Zhang, D., Stange, T., & Jenko, F. (2024). Global gyrokinetic analysis of Wendelstein 7-X discharge: unveiling the importance of trapped-electron-mode and electron-temperature-gradient turbulence. Nuclear Fusion, 64(9), Article 096040. https://doi.org/10.1088/1741-4326/ad6675

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title = "Global gyrokinetic analysis of Wendelstein 7-X discharge: unveiling the importance of trapped-electron-mode and electron-temperature-gradient turbulence",

abstract = "We present the first nonlinear, gyrokinetic, radially global simulation of a discharge of the Wendelstein 7-X-like stellarator, including kinetic electrons, an equilibrium radial electric field, as well as electromagnetic and collisional effects. By comparison against flux-tube and full-flux-surface simulations, we assess the impact of the equilibrium ExB-flow and flow shear on the stabilisation of turbulence. In contrast to the existing literature, we further provide substantial evidence for the turbulent electron heat flux being driven by trapped-electron-mode and electron-temperature-gradient turbulence in the core of the plasma. The former manifests as a hybrid together with ion-temperature-gradient turbulence and is primarily driven by the finite electron temperature gradient, which has largely been neglected in nonlinear stellarator simulations presented in the existing literature.",

keywords = "gyrokinetic simulations, stellarator turbulence, Wendelstein 7-X",

author = "{Wendelstein 7-X Team} and Felix Wilms and {Ba{\~n}{\'o}n Navarro}, Alejandro and Thomas Windisch and Sergey Bozhenkov and Felix Warmer and Golo Fuchert and Oliver Ford and Daihong Zhang and Torsten Stange and Frank Jenko",

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Wendelstein 7-X Team, Wilms, F, Bañón Navarro, A, Windisch, T, Bozhenkov, S, Warmer, F, Fuchert, G, Ford, O, Zhang, D, Stange, T & Jenko, F 2024, 'Global gyrokinetic analysis of Wendelstein 7-X discharge: unveiling the importance of trapped-electron-mode and electron-temperature-gradient turbulence', Nuclear Fusion, vol. 64, no. 9, 096040. https://doi.org/10.1088/1741-4326/ad6675

Global gyrokinetic analysis of Wendelstein 7-X discharge: unveiling the importance of trapped-electron-mode and electron-temperature-gradient turbulence. / Wendelstein 7-X Team; Wilms, Felix (Corresponding author); Bañón Navarro, Alejandro et al.
In: Nuclear Fusion, Vol. 64, No. 9, 096040, 09.2024.

Research output: Contribution to journal › Article › Academic › peer-review

TY - JOUR

T1 - Global gyrokinetic analysis of Wendelstein 7-X discharge

T2 - unveiling the importance of trapped-electron-mode and electron-temperature-gradient turbulence

AU - Wendelstein 7-X Team

AU - Wilms, Felix

AU - Bañón Navarro, Alejandro

AU - Windisch, Thomas

AU - Bozhenkov, Sergey

AU - Warmer, Felix

AU - Fuchert, Golo

AU - Ford, Oliver

AU - Zhang, Daihong

AU - Stange, Torsten

AU - Jenko, Frank

PY - 2024/9

Y1 - 2024/9

N2 - We present the first nonlinear, gyrokinetic, radially global simulation of a discharge of the Wendelstein 7-X-like stellarator, including kinetic electrons, an equilibrium radial electric field, as well as electromagnetic and collisional effects. By comparison against flux-tube and full-flux-surface simulations, we assess the impact of the equilibrium ExB-flow and flow shear on the stabilisation of turbulence. In contrast to the existing literature, we further provide substantial evidence for the turbulent electron heat flux being driven by trapped-electron-mode and electron-temperature-gradient turbulence in the core of the plasma. The former manifests as a hybrid together with ion-temperature-gradient turbulence and is primarily driven by the finite electron temperature gradient, which has largely been neglected in nonlinear stellarator simulations presented in the existing literature.

AB - We present the first nonlinear, gyrokinetic, radially global simulation of a discharge of the Wendelstein 7-X-like stellarator, including kinetic electrons, an equilibrium radial electric field, as well as electromagnetic and collisional effects. By comparison against flux-tube and full-flux-surface simulations, we assess the impact of the equilibrium ExB-flow and flow shear on the stabilisation of turbulence. In contrast to the existing literature, we further provide substantial evidence for the turbulent electron heat flux being driven by trapped-electron-mode and electron-temperature-gradient turbulence in the core of the plasma. The former manifests as a hybrid together with ion-temperature-gradient turbulence and is primarily driven by the finite electron temperature gradient, which has largely been neglected in nonlinear stellarator simulations presented in the existing literature.

KW - gyrokinetic simulations

KW - stellarator turbulence

KW - Wendelstein 7-X

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DO - 10.1088/1741-4326/ad6675

M3 - Article

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SN - 0029-5515

VL - 64

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 9

M1 - 096040

ER -

Global gyrokinetic analysis of Wendelstein 7-X discharge: unveiling the importance of trapped-electron-mode and electron-temperature-gradient turbulence

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