PM4Stell: A prototype permanent magnet stellarator structure

Caoxiang Zhu; Kenneth Hammond; Adam Rutkowski; Keith Corrigan; Douglas Bishop; Arthur Brooks; Peter Dugan; Robert Ellis; Luke Perkins; Yuhu Zhai; Amelia Chambliss; David Gates; Dennis Steward; Craig Miller; Bob Lown; Robert Mercurio

doi:10.1063/5.0102754

PM4Stell: A prototype permanent magnet stellarator structure

Caoxiang Zhu, Kenneth Hammond, Adam Rutkowski, Keith Corrigan, Douglas Bishop, Arthur Brooks, Peter Dugan, Robert Ellis, Luke Perkins, Yuhu Zhai, Amelia Chambliss, David Gates, Dennis Steward, Craig Miller, Bob Lown, Robert Mercurio

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

12 Scopus citations

Abstract

Permanent magnets provide a possible solution to simplify complicated stellarator coils. A prototype permanent magnet stellarator structure, PM4Stell, has been funded to demonstrate the technical feasibility of using permanent magnets to create the shaping field of a stellarator. Permanent magnets in uniform cubes with three polarization directions will be carefully placed to generate the required magnetic field for a National Compact Stellarator eXperiment-like equilibrium together with planar toroidal field coils. Discrete magnets will be glued together and inserted into a "post-office-box-like"supporting structure. Electromagnetic and structural analyses have been done to validate the design. Error field correction magnets will be used to shim possible error fields. The design efforts of the prototype permanent magnet stellarator structure are discussed.

Original language	English (US)
Article number	112501
Journal	Physics of Plasmas
Volume	29
Issue number	11
DOIs	https://doi.org/10.1063/5.0102754
State	Published - Nov 1 2022

All Science Journal Classification (ASJC) codes

Condensed Matter Physics

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10.1063/5.0102754

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title = "PM4Stell: A prototype permanent magnet stellarator structure",

abstract = "Permanent magnets provide a possible solution to simplify complicated stellarator coils. A prototype permanent magnet stellarator structure, PM4Stell, has been funded to demonstrate the technical feasibility of using permanent magnets to create the shaping field of a stellarator. Permanent magnets in uniform cubes with three polarization directions will be carefully placed to generate the required magnetic field for a National Compact Stellarator eXperiment-like equilibrium together with planar toroidal field coils. Discrete magnets will be glued together and inserted into a {"}post-office-box-like{"}supporting structure. Electromagnetic and structural analyses have been done to validate the design. Error field correction magnets will be used to shim possible error fields. The design efforts of the prototype permanent magnet stellarator structure are discussed.",

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T2 - A prototype permanent magnet stellarator structure

AU - Zhu, Caoxiang

AU - Hammond, Kenneth

AU - Rutkowski, Adam

AU - Corrigan, Keith

AU - Bishop, Douglas

AU - Brooks, Arthur

AU - Dugan, Peter

AU - Ellis, Robert

AU - Perkins, Luke

AU - Zhai, Yuhu

AU - Chambliss, Amelia

AU - Gates, David

AU - Steward, Dennis

AU - Miller, Craig

AU - Lown, Bob

AU - Mercurio, Robert

PY - 2022/11/1

Y1 - 2022/11/1

N2 - Permanent magnets provide a possible solution to simplify complicated stellarator coils. A prototype permanent magnet stellarator structure, PM4Stell, has been funded to demonstrate the technical feasibility of using permanent magnets to create the shaping field of a stellarator. Permanent magnets in uniform cubes with three polarization directions will be carefully placed to generate the required magnetic field for a National Compact Stellarator eXperiment-like equilibrium together with planar toroidal field coils. Discrete magnets will be glued together and inserted into a "post-office-box-like"supporting structure. Electromagnetic and structural analyses have been done to validate the design. Error field correction magnets will be used to shim possible error fields. The design efforts of the prototype permanent magnet stellarator structure are discussed.

AB - Permanent magnets provide a possible solution to simplify complicated stellarator coils. A prototype permanent magnet stellarator structure, PM4Stell, has been funded to demonstrate the technical feasibility of using permanent magnets to create the shaping field of a stellarator. Permanent magnets in uniform cubes with three polarization directions will be carefully placed to generate the required magnetic field for a National Compact Stellarator eXperiment-like equilibrium together with planar toroidal field coils. Discrete magnets will be glued together and inserted into a "post-office-box-like"supporting structure. Electromagnetic and structural analyses have been done to validate the design. Error field correction magnets will be used to shim possible error fields. The design efforts of the prototype permanent magnet stellarator structure are discussed.

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JO - Physics of Plasmas

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IS - 11

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ER -

PM4Stell: A prototype permanent magnet stellarator structure

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