Numerical optimization of three-dimensional coils for NSTX-U3

S. A. Lazerson; J. K. Park; N. Logan; A. Boozer

doi:10.1088/0741-3335/57/10/104001

Numerical optimization of three-dimensional coils for NSTX-U³

S. A. Lazerson, J. K. Park, N. Logan, A. Boozer

PPPL NSTX

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

7 Scopus citations

Abstract

A tool for the calculation of optimal three-dimensional (3D) perturbative magnetic fields in tokamaks has been developed. The IPECOPT code builds upon the stellarator optimization code STELLOPT to allow for optimization of linear ideal magnetohydrodynamic perturbed equilibrium (IPEC). This tool has been applied to NSTX-U equilibria, addressing which fields are the most effective at driving NTV torques. The NTV torque calculation is performed by the PENT code. Optimization of the normal field spectrum shows that fields with n = 1 character can drive a large core torque. It is also shown that fields with n = 3 features are capable of driving edge torque and some core torque. Coil current optimization (using the planned in-vessel and existing RWM coils) on NSTX-U suggest the planned coils set is adequate for core and edge torque control. Comparison between error field correction experiments on DIII-D and the optimizer show good agreement.

Original language	English (US)
Article number	104001
Journal	Plasma Physics and Controlled Fusion
Volume	57
Issue number	10
DOIs	https://doi.org/10.1088/0741-3335/57/10/104001
State	Published - Oct 1 2015

All Science Journal Classification (ASJC) codes

Nuclear Energy and Engineering
Condensed Matter Physics

Keywords

equilibrium
in-vessel coils
optimization
rotation
tokamak
torque

Access to Document

10.1088/0741-3335/57/10/104001

Cite this

@article{04934814f3444b63adcb0bdef13e837a,

title = "Numerical optimization of three-dimensional coils for NSTX-U3",

abstract = "A tool for the calculation of optimal three-dimensional (3D) perturbative magnetic fields in tokamaks has been developed. The IPECOPT code builds upon the stellarator optimization code STELLOPT to allow for optimization of linear ideal magnetohydrodynamic perturbed equilibrium (IPEC). This tool has been applied to NSTX-U equilibria, addressing which fields are the most effective at driving NTV torques. The NTV torque calculation is performed by the PENT code. Optimization of the normal field spectrum shows that fields with n = 1 character can drive a large core torque. It is also shown that fields with n = 3 features are capable of driving edge torque and some core torque. Coil current optimization (using the planned in-vessel and existing RWM coils) on NSTX-U suggest the planned coils set is adequate for core and edge torque control. Comparison between error field correction experiments on DIII-D and the optimizer show good agreement.",

keywords = "equilibrium, in-vessel coils, optimization, rotation, tokamak, torque",

author = "Lazerson, \{S. A.\} and Park, \{J. K.\} and N. Logan and A. Boozer",

note = "Publisher Copyright: {\textcopyright} 2015 IOP Publishing Ltd.",

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T1 - Numerical optimization of three-dimensional coils for NSTX-U3

AU - Lazerson, S. A.

AU - Park, J. K.

AU - Logan, N.

AU - Boozer, A.

PY - 2015/10/1

Y1 - 2015/10/1

N2 - A tool for the calculation of optimal three-dimensional (3D) perturbative magnetic fields in tokamaks has been developed. The IPECOPT code builds upon the stellarator optimization code STELLOPT to allow for optimization of linear ideal magnetohydrodynamic perturbed equilibrium (IPEC). This tool has been applied to NSTX-U equilibria, addressing which fields are the most effective at driving NTV torques. The NTV torque calculation is performed by the PENT code. Optimization of the normal field spectrum shows that fields with n = 1 character can drive a large core torque. It is also shown that fields with n = 3 features are capable of driving edge torque and some core torque. Coil current optimization (using the planned in-vessel and existing RWM coils) on NSTX-U suggest the planned coils set is adequate for core and edge torque control. Comparison between error field correction experiments on DIII-D and the optimizer show good agreement.

AB - A tool for the calculation of optimal three-dimensional (3D) perturbative magnetic fields in tokamaks has been developed. The IPECOPT code builds upon the stellarator optimization code STELLOPT to allow for optimization of linear ideal magnetohydrodynamic perturbed equilibrium (IPEC). This tool has been applied to NSTX-U equilibria, addressing which fields are the most effective at driving NTV torques. The NTV torque calculation is performed by the PENT code. Optimization of the normal field spectrum shows that fields with n = 1 character can drive a large core torque. It is also shown that fields with n = 3 features are capable of driving edge torque and some core torque. Coil current optimization (using the planned in-vessel and existing RWM coils) on NSTX-U suggest the planned coils set is adequate for core and edge torque control. Comparison between error field correction experiments on DIII-D and the optimizer show good agreement.

KW - equilibrium

KW - in-vessel coils

KW - optimization

KW - rotation

KW - tokamak

KW - torque

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