Development and performance of a 2.9 Tesla dipole magnet using high-temperature superconducting CORC® wires. (7th December 2020)

Record Type:
Journal Article
Title:
Development and performance of a 2.9 Tesla dipole magnet using high-temperature superconducting CORC® wires. (7th December 2020)
Main Title:
Development and performance of a 2.9 Tesla dipole magnet using high-temperature superconducting CORC® wires
Authors:
Wang, Xiaorong
Abraimov, Dmytro
Arbelaez, Diego
Bogdanof, Timothy J
Brouwer, Lucas
Caspi, Shlomo
Dietderich, Daniel R
DiMarco, Joseph
Francis, Ashleigh
Garcia Fajardo, Laura
Ghiorso, William B
Gourlay, Stephen A
Higley, Hugh C
Marchevsky, Maxim
Maruszewski, Maxwell A
Myers, Cory S
Prestemon, Soren O
Shen, Tengming
Taylor, Jordan
Teyber, Reed
Turqueti, Marcos
van der Laan, Danko
Weiss, Jeremy D
Abstract:
Abstract: Although the high-temperature superconducting (HTS) REBa2 Cu3 O x (REBCO, RE–rare earth elements) material has a strong potential to enable dipole magnetic fields above 20 T in future circular particle colliders, the magnet and conductor technology needs to be developed. As part of an ongoing development to address this need, here we report on our CORC ® canted cos θ magnet called C2 with a target dipole field of 3 T in a 65 mm aperture. The magnet was wound with 70 m of 3.8 mm diameter CORC ® wire on machined metal mandrels. The wire had 30 commercial REBCO tapes from SuperPower Inc. each 2 mm wide with a 30 µ m thick substrate. The magnet generated a peak dipole field of 2.91 T at 6.290 kA, 4.2 K. The magnet could be consistently driven into the flux-flow regime with reproducible voltage rise at an engineering current density between 400–550 A mm −2, allowing reliable quench detection and magnet protection. The C2 magnet represents another successful step towards the development of high-field accelerator magnet and CORC ® conductor technologies. The test results highlighted two development needs: continue improving the performance and flexibility of CORC ® wires and develop the capability to identify locations of first onset of flux-flow voltage.
Is Part Of:
Superconductor science & technology. Volume 34:Number 1(2021)
Journal:
Superconductor science & technology
Issue:
Volume 34:Number 1(2021)
Issue Display:
Volume 34, Issue 1 (2021)
Year:
2021
Volume:
34
Issue:
1
Issue Sort Value:
2021-0034-0001-0000
Page Start:
Page End:
Publication Date:
2020-12-07
Subjects:
REBCO -- dipole accelerator magnet -- CORC®
Superconductivity -- Periodicals
Superconductors -- Periodicals
537.623
Journal URLs:
http://iopscience.iop.org/0953-2048
http://ioppublishing.org/
DOI:
10.1088/1361-6668/abc2a5
Languages:
English
ISSNs:
0953-2048
Deposit Type:
Legaldeposit
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