Benign Saturation of Ideal Ballooning Instability in a High-Performance Stellarator

Yao Zhou; K. Aleynikova; Chang Liu; N. M. Ferraro

doi:10.1103/PhysRevLett.133.135102

Benign Saturation of Ideal Ballooning Instability in a High-Performance Stellarator

Yao Zhou
, K. Aleynikova
, Chang Liu
, N. M. Ferraro

PPPL Theory

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

11 Scopus citations

Abstract

To examine the robustness of the designed 5% β limit for high-performance operation in the W7-X stellarator, we undertake nonlinear magnetohydrodynamic (MHD) simulations of pressure-driven instabilities using the m3d-c1 code. Consistent with linear analyses, ideal ballooning instabilities occur as β exceeds 5% in the standard configuration. Nonetheless, the modes saturate nonlinearly at relatively low levels without triggering large-scale crashes, even though confinement degradation worsens as β increases. In contrast, in an alternative configuration with nearly zero magnetic shear, ideal interchange modes induce a pressure crash at β=1%. These results suggest that the standard W7-X configuration might have a soft β limit that is fairly immune to major MHD events, which enhances the appeal of the stellarator approach to steady-state fusion reactors.

Original language	English (US)
Article number	135102
Journal	Physical review letters
Volume	133
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevLett.133.135102
State	Published - Sep 27 2024

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.133.135102

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title = "Benign Saturation of Ideal Ballooning Instability in a High-Performance Stellarator",

abstract = "To examine the robustness of the designed 5\% β limit for high-performance operation in the W7-X stellarator, we undertake nonlinear magnetohydrodynamic (MHD) simulations of pressure-driven instabilities using the m3d-c1 code. Consistent with linear analyses, ideal ballooning instabilities occur as β exceeds 5\% in the standard configuration. Nonetheless, the modes saturate nonlinearly at relatively low levels without triggering large-scale crashes, even though confinement degradation worsens as β increases. In contrast, in an alternative configuration with nearly zero magnetic shear, ideal interchange modes induce a pressure crash at β=1\%. These results suggest that the standard W7-X configuration might have a soft β limit that is fairly immune to major MHD events, which enhances the appeal of the stellarator approach to steady-state fusion reactors.",

author = "Yao Zhou and K. Aleynikova and Chang Liu and Ferraro, \{N. M.\}",

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T1 - Benign Saturation of Ideal Ballooning Instability in a High-Performance Stellarator

AU - Zhou, Yao

AU - Aleynikova, K.

AU - Liu, Chang

AU - Ferraro, N. M.

PY - 2024/9/27

Y1 - 2024/9/27

N2 - To examine the robustness of the designed 5% β limit for high-performance operation in the W7-X stellarator, we undertake nonlinear magnetohydrodynamic (MHD) simulations of pressure-driven instabilities using the m3d-c1 code. Consistent with linear analyses, ideal ballooning instabilities occur as β exceeds 5% in the standard configuration. Nonetheless, the modes saturate nonlinearly at relatively low levels without triggering large-scale crashes, even though confinement degradation worsens as β increases. In contrast, in an alternative configuration with nearly zero magnetic shear, ideal interchange modes induce a pressure crash at β=1%. These results suggest that the standard W7-X configuration might have a soft β limit that is fairly immune to major MHD events, which enhances the appeal of the stellarator approach to steady-state fusion reactors.

AB - To examine the robustness of the designed 5% β limit for high-performance operation in the W7-X stellarator, we undertake nonlinear magnetohydrodynamic (MHD) simulations of pressure-driven instabilities using the m3d-c1 code. Consistent with linear analyses, ideal ballooning instabilities occur as β exceeds 5% in the standard configuration. Nonetheless, the modes saturate nonlinearly at relatively low levels without triggering large-scale crashes, even though confinement degradation worsens as β increases. In contrast, in an alternative configuration with nearly zero magnetic shear, ideal interchange modes induce a pressure crash at β=1%. These results suggest that the standard W7-X configuration might have a soft β limit that is fairly immune to major MHD events, which enhances the appeal of the stellarator approach to steady-state fusion reactors.

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Benign Saturation of Ideal Ballooning Instability in a High-Performance Stellarator

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