Direct microstability optimization of stellarator devices

R. Jorge; W. Dorland; P. Kim; M. Landreman; N. R. Mandell; G. Merlo; T. Qian

doi:10.1103/PhysRevE.110.035201

Direct microstability optimization of stellarator devices

R. Jorge
, W. Dorland
, P. Kim
, M. Landreman
, N. R. Mandell
, G. Merlo
, T. Qian

PPPL Computational Science

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

6 Scopus citations

Abstract

Turbulent transport is regarded as one of the key issues in magnetic confinement nuclear fusion, both for tokamaks and stellarators. In this work, we show that a significant decrease in a microstability-based proxy, as opposed to a geometric one, for the turbulent heat flux, namely the quasilinear heat flux, can be obtained in an efficient manner by coupling stellarator optimization with linear gyrokinetic simulations. This is accomplished by computing the quasilinear heat flux at each step of the optimization process, as well as the deviation from quasisymmetry, and minimizing their sum, leading to a balance between neoclassical and the turbulent transport proxy.

Original language	English (US)
Article number	035201
Journal	Physical Review E
Volume	110
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevE.110.035201
State	Published - Sep 2024

All Science Journal Classification (ASJC) codes

Statistical and Nonlinear Physics
Statistics and Probability
Condensed Matter Physics

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10.1103/PhysRevE.110.035201

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title = "Direct microstability optimization of stellarator devices",

abstract = "Turbulent transport is regarded as one of the key issues in magnetic confinement nuclear fusion, both for tokamaks and stellarators. In this work, we show that a significant decrease in a microstability-based proxy, as opposed to a geometric one, for the turbulent heat flux, namely the quasilinear heat flux, can be obtained in an efficient manner by coupling stellarator optimization with linear gyrokinetic simulations. This is accomplished by computing the quasilinear heat flux at each step of the optimization process, as well as the deviation from quasisymmetry, and minimizing their sum, leading to a balance between neoclassical and the turbulent transport proxy.",

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AU - Jorge, R.

AU - Dorland, W.

AU - Kim, P.

AU - Landreman, M.

AU - Mandell, N. R.

AU - Merlo, G.

AU - Qian, T.

PY - 2024/9

Y1 - 2024/9

N2 - Turbulent transport is regarded as one of the key issues in magnetic confinement nuclear fusion, both for tokamaks and stellarators. In this work, we show that a significant decrease in a microstability-based proxy, as opposed to a geometric one, for the turbulent heat flux, namely the quasilinear heat flux, can be obtained in an efficient manner by coupling stellarator optimization with linear gyrokinetic simulations. This is accomplished by computing the quasilinear heat flux at each step of the optimization process, as well as the deviation from quasisymmetry, and minimizing their sum, leading to a balance between neoclassical and the turbulent transport proxy.

AB - Turbulent transport is regarded as one of the key issues in magnetic confinement nuclear fusion, both for tokamaks and stellarators. In this work, we show that a significant decrease in a microstability-based proxy, as opposed to a geometric one, for the turbulent heat flux, namely the quasilinear heat flux, can be obtained in an efficient manner by coupling stellarator optimization with linear gyrokinetic simulations. This is accomplished by computing the quasilinear heat flux at each step of the optimization process, as well as the deviation from quasisymmetry, and minimizing their sum, leading to a balance between neoclassical and the turbulent transport proxy.

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VL - 110

JO - Physical Review E

JF - Physical Review E

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ER -

Direct microstability optimization of stellarator devices

Abstract

All Science Journal Classification (ASJC) codes

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