Development of metal Hall detector for magnetic field
measurement in a tokamak

doi:10.16568/j.0254-6086.202303011

Abstract

Abstract: The metal Hall detector is one of the most important diagnostics for magnetic field measurement of magnetically confined fusion reactor in future. The development of the metal Hall detector system is introduced, including the principles of measurement, the manufacture technology of the detector, the development of the electronics system, the construction of the calibration system and the test results. The metal bismuth is used as the Hall material, the thickness of the active region is 100nm, and the factor of the amplifier is 2000-200000 times. The test results show that when the magnetic field is above 30Gs, the measuring accuracy of the system is better than ±1%, which can reach the calibration accuracy of the magnetic probe and meet the magnetic field measurement requirements of a tokamak.

Key words: Tokamak, Metal Hall detector, Hall effect, Magnetic measurement

摘要： 金属霍尔探测器被认为是未来磁约束聚变堆磁场测量的重要工具之一。介绍了金属霍尔探测器系统的研制，包括测量原理、探测器制作工艺、电子学系统研制、标定系统建设及测试结果等。采用金属铋作为霍尔材料，有源区厚度为 100nm，放大器的放大倍数为 2000~200000 倍。测试结果显示，当待测磁场在3mT以上时，系统的测量精度优于±1%，可以达到磁探针的标定精度，能够满足托卡马克装置的磁场测量要求。

关键词: 托卡马克, 金属霍尔探测器, 霍尔效应, 磁场测量

CLC Number:

TL65+ 5

WANG Ao , JI Xiao-quan, SUN Teng-fei, LIANG Shao-yong, ZHANG Jun-zhao, CUI Bu-tian, GAO Jin-ming, YANG Qing-wei . Development of metal Hall detector for magnetic field measurement in a tokamak [J]. Nuclear Fusion and Plasma Physics, 2023, 43(3): 317-323.

王傲, 季小全, 孙腾飞, 梁绍勇, 张均钊, 崔步天, 高金明, 杨青巍. 用于托卡马克磁场测量的金属霍尔探测器的研制[J]. 核工业西南物理研究院, 2023, 43(3): 317-323.

References

[1] 石秉仁. 磁约束核聚变原理与实践 [M]. 北京: 原子能出版社, 1999.15-19.

[2] Vayakis G, Walker C, the ITER International team and participant team. Magnetic diagnostics for ITER/BPX plasmas [J]. Rev. Sci. Instrum., 2003, 74: 2409–2417.

[3] Orsitto F P, Villari R, Moro F, et al. Diagnostics and control for the steady state and pulsed tokamak DEMO [J]. Nucl. Fusion, 2016, 56(2): 026009.

[4] Nieuwenhove R Van, Vermeeren L. Study of the radiation induced electromotive force effect on mineral insulated cables for magnetic diagnostics in ITER [J]. Fusion engineering and design, 2003, 66‒68: 821-825.

[5] Xu Y, Ji X, Yang Q, et al. Development of a low-drift integrator system on the HL-2A tokamak [J]. Rev. Sci. Instrum., 2016, 87(2): 023507.

[6] Ďuran I. Prospects of steady state magnetic diagnostic of fusion reactors based on metallic Hall sensors [A]. AIP Conference Proceedings [C]. USA: American Institute of Physics, 2012. 317–324.

[7] Entler S, Duran I, Kocan M, et al. Prospects for the steady-state magnetic diagnostic based on antimony Hall sensors for future fusion power reactors [J]. Fusion Engineering and Design, 2019, 146: 526-530.

[8] Sentkerestiová J, Ďuran I, Kovařík K, et al. Performance of metal Hall sensors based on copper [J]. Fusion Engineering and Design, 2013, 88(6-8): 1310-1314.

[9] Popovic R S. Hall effect devices: magnetic sensors and characterization of semiconductors [M]. Philadelphia: Institute of Physics Pub, 2004.

[10] Kittel C. Introduction to Solid State Physics [M]. USA: John Wiley & Sons, Inc., 1996.

[11] Ivan Ďuran, Slavomír Entler, Martin Kočan, et al. Development of Bismuth Hall sensors for ITER steady state magnetic diagnostics [J]. Fusion Engineering and Design, 2017, 123: 690-694.

[12] Temperature dependence of the Hall coefficient of sensitive layer materials considered for DEMO Hall sensors [J]. Fusion Engineering and Design, 2020, 153: 111454.

[13] Ďuran I, Entler S, Kohout M, et al. High magnetic field test of bismuth Hall sensors for ITER steady state magnetic diagnostic [J]. The Review of scientific instruments, 2016, 87(11): 11D46.

[14] Kocan M, Duran I, Entler S, et al. Steady state magnetic sensors for ITER and beyond: development and final design (invited) [J]. The Review of scientific instruments, 2018, 89(10): 10J119.

[15] Van Herwaarden A W. The Seebeck effect in silicon ICs [J]. Sensors and Actuators, 1984, 6(4): 245-254.

[16] Munter P J A. Spinning-current method for offset reduction in silicon Hall plates [J]. 1992.

Development of metal Hall detector for magnetic field measurement in a tokamak

用于托卡马克磁场测量的金属霍尔探测器的研制

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

[1]	ZHANG Yi-heng, ZHAO Zi-qiang, LI Zai-xin, CAI Lai-zhong. Skyshine simulation of HL-3 tokamak and shielding analysis based on cosRMC [J]. Nuclear Fusion and Plasma Physics, 2025, 45(1): 7-12.
[2]	XU Jie, CAI Li-jun, LIU Jian, LU Yong, ZHANG Long, LIU Kuan-cheng, HUANG Wen-yu, LIU Yu-xiang, LUO Shan. Development of the HL-3 first wall temperature monitoring system [J]. Nuclear Fusion and Plasma Physics, 2025, 45(1): 58-63.
[3]	WANG Jia-qi, MENG Jian-peng, JIA Rui-bao, LIU Xiao-long, LI Qiang, CHEN Xin, XIE Yan-feng. Thermal analysis of toroidal field coils on HL-3 tokamak [J]. Nuclear Fusion and Plasma Physics, 2024, 44(4): 401-408.
[4]	WANG Hong-zhi, PENG Jian-fei, WANG Ying-qiao, LI Hua-jun, XUAN Wei-min. Simulation study of megawatt-class supercapacitor energy storage system supplying power to central solenoid [J]. Nuclear Fusion and Plasma Physics, 2024, 44(4): 415-422.
[5]	WANG Sheng-qing, , WANG Zhan-hui, TANG Teng-fei, XU Xin-liang, CHEN Jian, WANG Zhi-bin. Numerical simulation of edge-localized mode at the pedestal region in the HL-3 tokamak [J]. Nuclear Fusion and Plasma Physics, 2024, 44(4): 470-476.
[6]	HE Xiao-xue, CHEN Wen-jin, WEI Yan-ling, LIU Liang, WANG Shi-qin, YU De-liang. The development of charge exchange recombination spectroscopy diagnostic system on the HL-3 tokamak [J]. Nuclear Fusion and Plasma Physics, 2024, 44(4): 477-482.
[7]	ZHENG Wan-xin, YE Ji-ruo, CHEN Gang-yu, ZHANG Feng, HUANG Mei . Improvement and test of the optical path of ECRH No.1 upper launcher on HL-3 tokamak [J]. Nuclear Fusion and Plasma Physics, 2024, 44(3): 256-261.
[8]	TANG Le, CAI Li-jun, LU Yong, YUAN Ying-long, HOU Ji-lai, ZHANG Long, LIU Kuan-cheng, LAI Chun-lin . Analysis of the seismic response spectrum of the HL-3 carbon-based first wall [J]. Nuclear Fusion and Plasma Physics, 2024, 44(3): 262-266.
[9]	LI Ning, XU Hao , YANG Qing-xi , CHEN Jian , CHEN Shi-lin, LU Kun. Design of water-cooling structure for spherical tokamak magnet based on the Fluent [J]. Nuclear Fusion and Plasma Physics, 2024, 44(3): 282-289.
[10]	ZHOU Yu-jie, HAO Guang-zhou, ZHU Yi-ren, XUE Miao . Simulation on the impact of diamagnetic drift on edge localized modes [J]. Nuclear Fusion and Plasma Physics, 2024, 44(3): 351-358.
[11]	SHAO Li-hua, LIU Ze-kang, LI Zai-xin, CAI Lai-zhong . Influence of Soret and Dufour effect coupling on double diffusion of deuterium concentration and temperature in HL-2A diverter target plate [J]. Nuclear Fusion and Plasma Physics, 2024, 44(3): 367-372.
[12]	SHEN Yong, DONG Jia-qi, LI Jia, HAN Ming-kun, SHEN Yu-hang, ZHANG Xiao-ran, LIU Jia-yan, WANG Zhan-hui, LI Ji-quan . Preliminary study on low frequency drift mode database and its machine learning on the HL-2A tokamak [J]. Nuclear Fusion and Plasma Physics, 2024, 44(2): 141-148.
[13]	ZHU Xiao-bo, XIA Fan, YANG Zong-yu, LIU Feng-wu, GONG Xin-wen, LIU Yu-hang, ZHANG Yi, SHI Pei-wan, CHEN Wei, YU Li-ming, CHEN Zheng-wei, ZHONG Wu-lü. Research on HL-2A fishbone mode recognition algorithm based on deep learning [J]. Nuclear Fusion and Plasma Physics, 2024, 44(2): 149-156.
[14]	TANG Le, CAI Li-jun, LU Yong, YUAN Ying-long, HOU Ji-lai, ZHANG Long, LIU Kuan-cheng, LAI Chun-lin . Preload analysis of screw bolt joints on the HL-3 carbon-based first wall [J]. Nuclear Fusion and Plasma Physics, 2024, 44(2): 177-182.
[15]	CHEN Xiao-lu, LI Peng-yuan, WEI Hai-hong, XU Wan-yun, CHEN Hui. Research on virtual simulation of motion trajectory of remote handling manipulator in a tokamak [J]. Nuclear Fusion and Plasma Physics, 2024, 44(2): 191-197.