Monofilament MgB2 Wire for a Whole-Body MRI Magnet: Superconducting Joints and Test Coils

This paper presents recent results from our continued development of a 0.5 T whole-body MRI magnet at the Francis Bitter Magnet Laboratory. HyperTech Research Corp. (Columbus, OH) manufactures the MgB 2 conductor for this project. During the past year, we have found that our technique, originally de...

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Bibliographic Details
Published in:IEEE transactions on applied superconductivity 2013-06, Vol.23 (3)
Main Authors: JIAYIN LING, VOCCIO, John, KIM, Youngjae, HAHN, Seungyong, BASCUNAN, Juan, PARK, Dongkeun K, IWASA, Yukikazu
Format: Article
Language:English
Subjects:
Applied sciences
Circuit properties
Electric, optical and optoelectronic circuits
Electrical engineering. Electrical power engineering
Electromagnets
Electronic circuits
Electronics
Exact sciences and technology
Materials
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Superconducting devices
Switching, multiplexing, switched capacity circuits
Various equipment and components
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Summary:This paper presents recent results from our continued development of a 0.5 T whole-body MRI magnet at the Francis Bitter Magnet Laboratory. HyperTech Research Corp. (Columbus, OH) manufactures the MgB 2 conductor for this project. During the past year, we have found that our technique, originally developed successfully to splice unreacted multifilament MgB 2 wires, works much better, i.e., of higher reliability, with unreacted monofilament MgB 2 wires. This has led us to wind the entire coil components in our persistent-mode MRI magnet with unreacted monofilament MgB 2 wire, having a MgB 2 core of 0.4 mm in diameter, an overall diameter of 0.8 mm bare, 1 mm S-glass insulated. To verify that these coils would not suffer from flux jumping, as they would if wound with monofilament NbTi wire, magnetization studies were performed on monofilament wires of MgB 2 and NbTi (as a reference) at 4.2 K. For the monofilament MgB 2 wire, the results were affirmative. To further ensure the absence of flux jumping that may quench these current-carrying coils, two test coils were wound with unreacted monofilament MgB 2 wire. One MgB 2 coil was operated in driven mode, while the other MgB 2 coil, equipped with a persistent current switch and terminated with a superconducting joint, was operated in persistent mode. The operating temperature range was 4.2–15 K for these MgB 2 coils. The driven mode coil was operated in self-field. The persistent mode coil achieved a persistent current of 100 A, corresponding to a self-field of ~ 1 T in the winding, for 1 hour with no measurable decay. Both test coils were operated quench free.
ISSN:1051-8223
1558-2515
DOI:10.1109/TASC.2012.2234183