Reactor-scale stellarators with force and torque minimized dipole coils

Alan A. Kaptanoglu; Alexander Wiedman; Jacob Halpern; Siena Hurwitz; Elizabeth J. Paul; Matt Landreman

doi:10.1088/1741-4326/adc318

Reactor-scale stellarators with force and torque minimized dipole coils

Alan A. Kaptanoglu, Alexander Wiedman, Jacob Halpern, Siena Hurwitz, Elizabeth J. Paul, Matt Landreman

Mathematics

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

Abstract

In this work, we utilize new coil objectives for stellarator optimization with autodifferentiation, including pointwise and net coil-coil forces and torques. We use these methods to perform the first large-scale optimization of planar dipole coil arrays, since arrays of small and geometrically simple coils have been proposed to partially produce the 3D magnetic fields for stellarators, generate advantageous magnetic field perturbations in tokamaks, and provide active, real-time control capabilities. We perform an ablation study to show that minimizing the orientation and location of each coil may be essential to get coil forces, coil torques, and field errors to tolerable levels. We conclude with solutions for three reactor-scale quasi-symmetric stellarators by jointly optimizing nonplanar TF coils and planar coil arrays.

Original language	English (US)
Article number	046029
Journal	Nuclear Fusion
Volume	65
Issue number	4
DOIs	https://doi.org/10.1088/1741-4326/adc318
State	Published - Apr 1 2025

Keywords

autodifferentiation
coil optimization
dipole coils
magnetostatics
nuclear fusion
stellarators

ASJC Scopus subject areas

Nuclear and High Energy Physics
Condensed Matter Physics

Access to Document

10.1088/1741-4326/adc318

Cite this

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title = "Reactor-scale stellarators with force and torque minimized dipole coils",

abstract = "In this work, we utilize new coil objectives for stellarator optimization with autodifferentiation, including pointwise and net coil-coil forces and torques. We use these methods to perform the first large-scale optimization of planar dipole coil arrays, since arrays of small and geometrically simple coils have been proposed to partially produce the 3D magnetic fields for stellarators, generate advantageous magnetic field perturbations in tokamaks, and provide active, real-time control capabilities. We perform an ablation study to show that minimizing the orientation and location of each coil may be essential to get coil forces, coil torques, and field errors to tolerable levels. We conclude with solutions for three reactor-scale quasi-symmetric stellarators by jointly optimizing nonplanar TF coils and planar coil arrays.",

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author = "Kaptanoglu, {Alan A.} and Alexander Wiedman and Jacob Halpern and Siena Hurwitz and Paul, {Elizabeth J.} and Matt Landreman",

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T1 - Reactor-scale stellarators with force and torque minimized dipole coils

AU - Kaptanoglu, Alan A.

AU - Wiedman, Alexander

AU - Halpern, Jacob

AU - Hurwitz, Siena

AU - Paul, Elizabeth J.

AU - Landreman, Matt

PY - 2025/4/1

Y1 - 2025/4/1

N2 - In this work, we utilize new coil objectives for stellarator optimization with autodifferentiation, including pointwise and net coil-coil forces and torques. We use these methods to perform the first large-scale optimization of planar dipole coil arrays, since arrays of small and geometrically simple coils have been proposed to partially produce the 3D magnetic fields for stellarators, generate advantageous magnetic field perturbations in tokamaks, and provide active, real-time control capabilities. We perform an ablation study to show that minimizing the orientation and location of each coil may be essential to get coil forces, coil torques, and field errors to tolerable levels. We conclude with solutions for three reactor-scale quasi-symmetric stellarators by jointly optimizing nonplanar TF coils and planar coil arrays.

AB - In this work, we utilize new coil objectives for stellarator optimization with autodifferentiation, including pointwise and net coil-coil forces and torques. We use these methods to perform the first large-scale optimization of planar dipole coil arrays, since arrays of small and geometrically simple coils have been proposed to partially produce the 3D magnetic fields for stellarators, generate advantageous magnetic field perturbations in tokamaks, and provide active, real-time control capabilities. We perform an ablation study to show that minimizing the orientation and location of each coil may be essential to get coil forces, coil torques, and field errors to tolerable levels. We conclude with solutions for three reactor-scale quasi-symmetric stellarators by jointly optimizing nonplanar TF coils and planar coil arrays.

KW - autodifferentiation

KW - coil optimization

KW - dipole coils

KW - magnetostatics

KW - nuclear fusion

KW - stellarators

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Reactor-scale stellarators with force and torque minimized dipole coils

Abstract

Keywords

ASJC Scopus subject areas

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