Dipole Magnets Above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors

To enable the physics research that continues to deepen our understanding of the Universe, future circular colliders will require a critical and unique instrument—magnets that can generate a dipole field of 20 T and above. However, today’s maturing magnet technology for low-temperature superconducto...
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Autor*in:	Xiaorong Wang [verfasserIn] Stephen A. Gourlay [verfasserIn] Soren O. Prestemon [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2019

Schlagwörter:	rebco accelerator magnet technology development

Übergeordnetes Werk:	In: Instruments - MDPI AG, 2018, 3(2019), 4, p 62
Übergeordnetes Werk:	volume:3 ; year:2019 ; number:4, p 62

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.3390/instruments3040062

Katalog-ID:	DOAJ012413534

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callnumber-first	Q - Science
author	Xiaorong Wang
spellingShingle	Xiaorong Wang misc QC1-999 misc QC770-798 misc rebco misc accelerator magnet misc technology development misc Physics misc Nuclear and particle physics. Atomic energy. Radioactivity Dipole Magnets Above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors
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topic_title	QC1-999 QC770-798 Dipole Magnets Above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors rebco accelerator magnet technology development
topic	misc QC1-999 misc QC770-798 misc rebco misc accelerator magnet misc technology development misc Physics misc Nuclear and particle physics. Atomic energy. Radioactivity
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title	Dipole Magnets Above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors
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title_full	Dipole Magnets Above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors
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author_browse	Xiaorong Wang Stephen A. Gourlay Soren O. Prestemon
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title_sort	dipole magnets above 20 tesla: research needs for a path via high-temperature superconducting rebco conductors
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title_auth	Dipole Magnets Above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors
abstract	To enable the physics research that continues to deepen our understanding of the Universe, future circular colliders will require a critical and unique instrument—magnets that can generate a dipole field of 20 T and above. However, today’s maturing magnet technology for low-temperature superconductors (Nb-Ti and Nb<inline-formula< <math display="inline"< <semantics< <msub< <mrow<</mrow< <mn<3</mn< </msub< </semantics< </math< </inline-formula<Sn) can lead to a maximum dipole field of around 16 T. High-temperature superconductors such as REBCO can, in principle, generate higher dipole fields but significant challenges exist for both conductor and magnet technology. To address these challenges, several critical research needs, including direct needs on instrumentation and measurements, are identified to push for the maximum dipole fields a REBCO accelerator magnet can generate. We discuss the research needs by reviewing the current results and outlining the perspectives for future technology development, followed by a brief update on the status of the technology development at Lawrence Berkeley National Laboratory. We present a roadmap for the next decade to develop 20 T-class REBCO accelerator magnets as an enabling instrument for future energy-frontier accelerator complex.
abstractGer	To enable the physics research that continues to deepen our understanding of the Universe, future circular colliders will require a critical and unique instrument—magnets that can generate a dipole field of 20 T and above. However, today’s maturing magnet technology for low-temperature superconductors (Nb-Ti and Nb<inline-formula< <math display="inline"< <semantics< <msub< <mrow<</mrow< <mn<3</mn< </msub< </semantics< </math< </inline-formula<Sn) can lead to a maximum dipole field of around 16 T. High-temperature superconductors such as REBCO can, in principle, generate higher dipole fields but significant challenges exist for both conductor and magnet technology. To address these challenges, several critical research needs, including direct needs on instrumentation and measurements, are identified to push for the maximum dipole fields a REBCO accelerator magnet can generate. We discuss the research needs by reviewing the current results and outlining the perspectives for future technology development, followed by a brief update on the status of the technology development at Lawrence Berkeley National Laboratory. We present a roadmap for the next decade to develop 20 T-class REBCO accelerator magnets as an enabling instrument for future energy-frontier accelerator complex.
abstract_unstemmed	To enable the physics research that continues to deepen our understanding of the Universe, future circular colliders will require a critical and unique instrument—magnets that can generate a dipole field of 20 T and above. However, today’s maturing magnet technology for low-temperature superconductors (Nb-Ti and Nb<inline-formula< <math display="inline"< <semantics< <msub< <mrow<</mrow< <mn<3</mn< </msub< </semantics< </math< </inline-formula<Sn) can lead to a maximum dipole field of around 16 T. High-temperature superconductors such as REBCO can, in principle, generate higher dipole fields but significant challenges exist for both conductor and magnet technology. To address these challenges, several critical research needs, including direct needs on instrumentation and measurements, are identified to push for the maximum dipole fields a REBCO accelerator magnet can generate. We discuss the research needs by reviewing the current results and outlining the perspectives for future technology development, followed by a brief update on the status of the technology development at Lawrence Berkeley National Laboratory. We present a roadmap for the next decade to develop 20 T-class REBCO accelerator magnets as an enabling instrument for future energy-frontier accelerator complex.
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title_short	Dipole Magnets Above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors
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