Construction and Test of the 19.6-T Solid-Nitrogen-Cooled REBCO Insert Magnet for the MIT 1.3-GHz NMR System.

IF 4.2 1区物理与天体物理 Q2 PHYSICS, APPLIED Superconductor Science & Technology Pub Date : 2025-03-01 Epub Date: 2025-02-20

Fangliang Dong, Dongkeun Park, Patricia Sadde, Juan Bascuñán, Yukikazu Iwasa

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Abstract

This work presents the construction, testing, and analyses work of the 835-MHz high-temperature superconducting REBCO insert magnet (H835), a critical component of the ongoing MIT 1.3-GHz HTS/LTS NMR Magnet project (1.3G). H835 consists of 40 double-pancake coils operating in a solid nitrogen environment at temperatures ranging from 4 to 17 K. It is designed to generate a central magnetic field of 19.6 T within a 79.4-mm clear bore that will house a 54-mm standard warm bore in the future 1.3-GHz NMR system. Building on lessons learned from our previous 18.8-T REBCO insert magnet (H800), which experienced quenching in 2018 that resulted in permanent damage, several improvements have been implemented in this new H835 design and construction. We have charged H835 to the rated current of 230 A and maintained its central field of 19.43 T for over 15 hours without any issues before ramping down the current. The 0.17-T (0.87%) error field between measurement and design was due to screening current effect. H835 will be combined with the low-temperature superconducting 500-MHz background magnet (L500) to complete 1.3G. We believe that this solid-nitrogen-cooled H835 can provide valuable insights for developing high-field liquid-helium-free REBCO magnets.

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麻省理工学院1.3 ghz核磁共振系统用19.6 t固体氮冷却REBCO插入磁体的构建与测试。

这项工作介绍了835-MHz高温超导REBCO插入磁铁（H835）的构建、测试和分析工作，H835是正在进行的MIT 1.3-GHz HTS/LTS核磁共振磁铁项目（1.3G）的关键组成部分。H835由40个双煎饼线圈组成，在4至17 K的温度范围内的固体氮环境中工作。它的设计目的是在79.4毫米的透明孔内产生19.6 T的中心磁场，在未来的1.3 ghz核磁共振系统中，该孔将容纳54毫米的标准暖孔。从我们之前的18.8 t REBCO插入磁铁（H800）中吸取的经验教训，该磁铁在2018年经历淬火导致永久性损坏，在新的H835设计和构造中实施了几项改进。我们给H835充电到额定电流230a，在降低电流之前保持了19.43 T的中心磁场超过15小时，没有任何问题。测量值与设计值之间的误差范围为0.17-T(0.87%)，主要是由于筛选电流的影响。H835将与低温超导500-MHz背景磁铁（L500）结合完成1.3G。我们相信这种固体氮冷却的H835可以为开发高场无液氦REBCO磁体提供有价值的见解。

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来源期刊

Superconductor Science & Technology 物理-物理：凝聚态物理

CiteScore

6.80

自引率

27.80%

发文量

227

审稿时长

3 months

期刊介绍： Superconductor Science and Technology is a multidisciplinary journal for papers on all aspects of superconductivity. The coverage includes theories of superconductivity, the basic physics of superconductors, the relation of microstructure and growth to superconducting properties, the theory of novel devices, and the fabrication and properties of thin films and devices. It also encompasses the manufacture and properties of conductors, and their application in the construction of magnets and heavy current machines, together with enabling technology.