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

The 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

The 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

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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.

Originele taal-2	Engels
Artikelnummer	096040
Aantal pagina's	15
Tijdschrift	Nuclear Fusion
Volume	64
Nummer van het tijdschrift	9
DOI's	https://doi.org/10.1088/1741-4326/ad6675
Status	Gepubliceerd - sep. 2024

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The 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), Artikel 096040. https://doi.org/10.1088/1741-4326/ad6675

@article{f1139ea9d419428784cc70a9ccf28fdf,

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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The 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, nr. 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. / The Wendelstein 7-X Team; Wilms, Felix (Corresponding author); Bañón Navarro, Alejandro et al.
In: Nuclear Fusion, Vol. 64, Nr. 9, 096040, 09.2024.

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › 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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SN - 0029-5515

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JO - Nuclear Fusion

JF - Nuclear Fusion

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

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