Performance of the First 80-kA HTS CICC for High-Field Application in Future Fusion Reactors

Huan Jin; Guanyu Xiao; Chao Zhou; Chuanyi Zhao; Shijie Shi; Haihong Liu; Fang Liu; Huajun Liu; Yu Wu; Zuojiafeng Wu; Hugues Bajas; Jack Greenwood; Mattia Ortino; Kamil Sedlak; Valentina Corato; Richard Kamendje; Alexandre Torre; Arend Nijhuis; Giulio Anniballi; Arnaud Devred; Jinggang Qin; Yuntao Song; Jiangang Li

doi:10.1016/j.eng.2025.05.015

Performance of the First 80-kA HTS CICC for High-Field Application in Future Fusion Reactors

Huan Jin
, Guanyu Xiao
, Chao Zhou^*
, Chuanyi Zhao
, Shijie Shi
, Haihong Liu
, Fang Liu
, Huajun Liu
, Yu Wu
, Zuojiafeng Wu
, Hugues Bajas
, Jack Greenwood
, Mattia Ortino
, Kamil Sedlak
, Valentina Corato
, Richard Kamendje
, Alexandre Torre
, Arend Nijhuis
, Giulio Anniballi
, Arnaud Devred

Jinggang Qin, Yuntao Song, Jiangang Li

^*Corresponding author for this work

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

2 Citations (Scopus)

39 Downloads (Pure)

Abstract

A promising way to realize controlled nuclear fusion involves the use of magnetic fields to control and confine the hot plasma configuration. This approach requires superconductor magnets operating above 15 T for the next generation of fusion devices. Due to their high in-field transport current capacity, rare-Earth barium copper oxide (REBCO) coated conductors are promising materials for manufacturing of cable-in-conduit conductors (CICCs) for fusion. However, the high-aspect-ratio geometry makes it difficult to find a multi-tape CICC configuration that fulfills the high engineering current density requirements while retaining enough flexibility for winding large-scale magnets. Moreover, the multilayer structure and inherent brittleness make the REBCO tapes susceptible to degradation during CICC manufacturing and operation. For more than a decade, the development of a reliable REBCO-based CICC that can sustain the huge combined mechanical, thermal, and Lorentz loads without degradation has been ongoing, albeit with limited progress. In this paper, we report on a prototype REBCO CICC that can withstand an applied cyclic Lorentz load of at least 830 kN·m⁻¹, corresponding to a transport current of 80 kA at 10.85 T and 4.5 K. To our knowledge, this is the highest load achieved to date. The CICC uses 288 tapes wound into six strengthened sub-cables, making it capable of having a current sharing temperature, T_cs, of around 39 and 20 K when operated under 10.85 T with a current of 40 and 80 kA, respectively. Scaled to a 20-T peak field and 46.5-kA transport current, this provides a temperature margin of over 10 K with respect to an operating temperature of 4.5 K. In addition, no perceptible transport current performance degradation was observed after cyclic Lorentz loading, cyclic warm-up/cool-down (WUCD), and quench campaigns. The proposed REBCO CICC is a milestone in the development of high-temperature superconductors for large-scale and high-field magnet applications.

Original language	English
Pages (from-to)	182-190
Number of pages	9
Journal	Engineering
Volume	55
Early online date	3 Jun 2025
DOIs	https://doi.org/10.1016/j.eng.2025.05.015
Publication status	Published - Dec 2025

Keywords

Electromagnetic and thermal load
Fusion magnet
High-temperature superconductor
Operational stability
REBCO CICC

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Cite this

Jin, H., Xiao, G., Zhou, C., Zhao, C., Shi, S., Liu, H., Liu, F., Liu, H., Wu, Y., Wu, Z., Bajas, H., Greenwood, J., Ortino, M., Sedlak, K., Corato, V., Kamendje, R., Torre, A., Nijhuis, A., Anniballi, G., ... Li, J. (2025). Performance of the First 80-kA HTS CICC for High-Field Application in Future Fusion Reactors. Engineering, 55, 182-190. https://doi.org/10.1016/j.eng.2025.05.015

@article{4975e3ea126e4e469a96be057763f861,

title = "Performance of the First 80-kA HTS CICC for High-Field Application in Future Fusion Reactors",

abstract = "A promising way to realize controlled nuclear fusion involves the use of magnetic fields to control and confine the hot plasma configuration. This approach requires superconductor magnets operating above 15 T for the next generation of fusion devices. Due to their high in-field transport current capacity, rare-Earth barium copper oxide (REBCO) coated conductors are promising materials for manufacturing of cable-in-conduit conductors (CICCs) for fusion. However, the high-aspect-ratio geometry makes it difficult to find a multi-tape CICC configuration that fulfills the high engineering current density requirements while retaining enough flexibility for winding large-scale magnets. Moreover, the multilayer structure and inherent brittleness make the REBCO tapes susceptible to degradation during CICC manufacturing and operation. For more than a decade, the development of a reliable REBCO-based CICC that can sustain the huge combined mechanical, thermal, and Lorentz loads without degradation has been ongoing, albeit with limited progress. In this paper, we report on a prototype REBCO CICC that can withstand an applied cyclic Lorentz load of at least 830 kN·m−1, corresponding to a transport current of 80 kA at 10.85 T and 4.5 K. To our knowledge, this is the highest load achieved to date. The CICC uses 288 tapes wound into six strengthened sub-cables, making it capable of having a current sharing temperature, Tcs, of around 39 and 20 K when operated under 10.85 T with a current of 40 and 80 kA, respectively. Scaled to a 20-T peak field and 46.5-kA transport current, this provides a temperature margin of over 10 K with respect to an operating temperature of 4.5 K. In addition, no perceptible transport current performance degradation was observed after cyclic Lorentz loading, cyclic warm-up/cool-down (WUCD), and quench campaigns. The proposed REBCO CICC is a milestone in the development of high-temperature superconductors for large-scale and high-field magnet applications.",

keywords = "Electromagnetic and thermal load, Fusion magnet, High-temperature superconductor, Operational stability, REBCO CICC",

author = "Huan Jin and Guanyu Xiao and Chao Zhou and Chuanyi Zhao and Shijie Shi and Haihong Liu and Fang Liu and Huajun Liu and Yu Wu and Zuojiafeng Wu and Hugues Bajas and Jack Greenwood and Mattia Ortino and Kamil Sedlak and Valentina Corato and Richard Kamendje and Alexandre Torre and Arend Nijhuis and Giulio Anniballi and Arnaud Devred and Jinggang Qin and Yuntao Song and Jiangang Li",

note = "Publisher Copyright: {\textcopyright} 2025 THE AUTHORS",

year = "2025",

month = dec,

doi = "10.1016/j.eng.2025.05.015",

language = "English",

volume = "55",

pages = "182--190",

journal = "Engineering",

issn = "2095-8099",

publisher = "Elsevier Ltd",

}

Jin, H, Xiao, G, Zhou, C, Zhao, C, Shi, S, Liu, H, Liu, F, Liu, H, Wu, Y, Wu, Z, Bajas, H, Greenwood, J, Ortino, M, Sedlak, K, Corato, V, Kamendje, R, Torre, A, Nijhuis, A, Anniballi, G, Devred, A, Qin, J, Song, Y & Li, J 2025, 'Performance of the First 80-kA HTS CICC for High-Field Application in Future Fusion Reactors', Engineering, vol. 55, pp. 182-190. https://doi.org/10.1016/j.eng.2025.05.015

TY - JOUR

T1 - Performance of the First 80-kA HTS CICC for High-Field Application in Future Fusion Reactors

AU - Jin, Huan

AU - Xiao, Guanyu

AU - Zhou, Chao

AU - Zhao, Chuanyi

AU - Shi, Shijie

AU - Liu, Haihong

AU - Liu, Fang

AU - Liu, Huajun

AU - Wu, Yu

AU - Wu, Zuojiafeng

AU - Bajas, Hugues

AU - Greenwood, Jack

AU - Ortino, Mattia

AU - Sedlak, Kamil

AU - Corato, Valentina

AU - Kamendje, Richard

AU - Torre, Alexandre

AU - Nijhuis, Arend

AU - Anniballi, Giulio

AU - Devred, Arnaud

AU - Qin, Jinggang

AU - Song, Yuntao

AU - Li, Jiangang

PY - 2025/12

Y1 - 2025/12

N2 - A promising way to realize controlled nuclear fusion involves the use of magnetic fields to control and confine the hot plasma configuration. This approach requires superconductor magnets operating above 15 T for the next generation of fusion devices. Due to their high in-field transport current capacity, rare-Earth barium copper oxide (REBCO) coated conductors are promising materials for manufacturing of cable-in-conduit conductors (CICCs) for fusion. However, the high-aspect-ratio geometry makes it difficult to find a multi-tape CICC configuration that fulfills the high engineering current density requirements while retaining enough flexibility for winding large-scale magnets. Moreover, the multilayer structure and inherent brittleness make the REBCO tapes susceptible to degradation during CICC manufacturing and operation. For more than a decade, the development of a reliable REBCO-based CICC that can sustain the huge combined mechanical, thermal, and Lorentz loads without degradation has been ongoing, albeit with limited progress. In this paper, we report on a prototype REBCO CICC that can withstand an applied cyclic Lorentz load of at least 830 kN·m−1, corresponding to a transport current of 80 kA at 10.85 T and 4.5 K. To our knowledge, this is the highest load achieved to date. The CICC uses 288 tapes wound into six strengthened sub-cables, making it capable of having a current sharing temperature, Tcs, of around 39 and 20 K when operated under 10.85 T with a current of 40 and 80 kA, respectively. Scaled to a 20-T peak field and 46.5-kA transport current, this provides a temperature margin of over 10 K with respect to an operating temperature of 4.5 K. In addition, no perceptible transport current performance degradation was observed after cyclic Lorentz loading, cyclic warm-up/cool-down (WUCD), and quench campaigns. The proposed REBCO CICC is a milestone in the development of high-temperature superconductors for large-scale and high-field magnet applications.

AB - A promising way to realize controlled nuclear fusion involves the use of magnetic fields to control and confine the hot plasma configuration. This approach requires superconductor magnets operating above 15 T for the next generation of fusion devices. Due to their high in-field transport current capacity, rare-Earth barium copper oxide (REBCO) coated conductors are promising materials for manufacturing of cable-in-conduit conductors (CICCs) for fusion. However, the high-aspect-ratio geometry makes it difficult to find a multi-tape CICC configuration that fulfills the high engineering current density requirements while retaining enough flexibility for winding large-scale magnets. Moreover, the multilayer structure and inherent brittleness make the REBCO tapes susceptible to degradation during CICC manufacturing and operation. For more than a decade, the development of a reliable REBCO-based CICC that can sustain the huge combined mechanical, thermal, and Lorentz loads without degradation has been ongoing, albeit with limited progress. In this paper, we report on a prototype REBCO CICC that can withstand an applied cyclic Lorentz load of at least 830 kN·m−1, corresponding to a transport current of 80 kA at 10.85 T and 4.5 K. To our knowledge, this is the highest load achieved to date. The CICC uses 288 tapes wound into six strengthened sub-cables, making it capable of having a current sharing temperature, Tcs, of around 39 and 20 K when operated under 10.85 T with a current of 40 and 80 kA, respectively. Scaled to a 20-T peak field and 46.5-kA transport current, this provides a temperature margin of over 10 K with respect to an operating temperature of 4.5 K. In addition, no perceptible transport current performance degradation was observed after cyclic Lorentz loading, cyclic warm-up/cool-down (WUCD), and quench campaigns. The proposed REBCO CICC is a milestone in the development of high-temperature superconductors for large-scale and high-field magnet applications.

KW - Electromagnetic and thermal load

KW - Fusion magnet

KW - High-temperature superconductor

KW - Operational stability

KW - REBCO CICC

UR - https://www.scopus.com/pages/publications/105007735541

U2 - 10.1016/j.eng.2025.05.015

DO - 10.1016/j.eng.2025.05.015

M3 - Article

AN - SCOPUS:105007735541

SN - 2095-8099

VL - 55

SP - 182

EP - 190

JO - Engineering

JF - Engineering

ER -

Performance of the First 80-kA HTS CICC for High-Field Application in Future Fusion Reactors

Abstract

Keywords

UN SDGs

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