Electrical transport measurement system in pulsed high magnetic field based on rotation sample rod

Liu Qin-Ying; Wang Jun-Feng; Zuo Hua-Kun; Yang Ming; Han Xiao-Tao

doi:10.7498/aps.68.20191115

Abstract

In recent years, measuring the electrical transport properties of materials in different directions of applied magnetic field has become an important experimental study of topological quantum materials. With the development of condensed matter physics, scientific research has shown that under the ultra-high intensity pulsed magnetic field, the electrical transport study of materials may extend to the quantum limit region, and more abundant physical phenomena will be observed. However, in the existing electric transport measurement system, the rotation sample rod under the action of steady-state field presents a large size and significant eddy current effect, which makes it difficult to meet the requirements for pulsed field measurement, and the current commercial physical property measurement system (PPMS) can only operate under ±16 T steady magnetic field. In addition, the conventional rotation sample rod encounters the problems of insufficient angular resolution and space utilization when used in pulsed high magnetic environment. So there is an urgent need to develop a higher performance rotation measurement system. In view of the above background, in this paper we present a kind of electrical transport measurement system designed by Wuhan National High Magnetic Field Center (WHMFC), which consists of five modules: pulse power supply, pulse magnet, control center, cryogenic system, and signal measurement. The key component is the sample measuring rod with rotation function, which restricts the movement of the drawbar through a double-groove structure to achieve an angular change in a range from –5° to 185°. An angle calibration coil is mounted on the back of the sample stage. Based on the double-calibration method, the angle control accuracy of 0.1° is achieved. The temperature, magnetoresistance and Hall resistance signal are collected by the integrated circuit on sample stage and extracted by compensation circuit and virtual digital lock-in amplifier, and the accuracy of electric transport measurement is better than 0.1 mΩ. Furthermore, the effect of eddycurrent and material deformation at low temperatures are completely eliminated by using polyetheretherketone material, which effectively improves the stability and reliability of the rotation sample rod. Using this measuring rod, we complete a series of experiments in the 8 mm sample cavity in the center of the pulse magnet: the minimum ambient temperature reaches 1.3 K, the maximum magnetic field strength arrives at 65 T, and the direction angle of the magnetic field is able to change in a 190° range. Thus the universally applicable measurement system of electric transport experiment in pulsed high magnetic field is successfully established. In this paper, we elaborate the principle and device components of the measurement system, the design and fabrication of the angle measuring rod, and the calibration principle and measurement process. Relevant experimental results show that the system has important application value in the research of 3D Fermi surface, topological insulator surface state, quantum limit transport, superconductivity analysis, etc. Based on this system, the electrical transport experimental system at WHMFC provides an effective means for the relevant research teams (home and abroad) engaged in the exploration of the intrinsic physical characteristics of quantum materials in extremely pulsed high magnetic field and low temperature environment.

Keywords:

Authors and contacts

1.
Wuhan National High Magnetic Field Center, Huazhong University of Science and Technology, Wuhan 430074, China
2.
State Key Laboratory of Advanced Electromagnetic Engineering and Technology, Huazhong University of Science and Technology, Wuhan 430074, China

Corresponding author: Zuo Hua-Kun, zuohuakun@163.com ; Han Xiao-Tao, xthan@mail.hust.edu.cn

Funds: Project supported by the National Key Research and Development Program of China (Grant No. 2016YFA0401703)

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References

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Cited By

图 1 脉冲强磁场电输运测量系统

Figure 1. Electrical transport measurement system in pulsed high magnetic field.

DownLoad: Full-Size Img PowerPoint

图 2 国内外已有转角样品杆　(a) 稳态强磁场中使用的探测样品杆; (b) 美国国家脉冲强磁场中心样品杆

Figure 2. Rotation sample rod in: (a) Steady-state strong magnetic field; (b) NHMFL (National High Magnetic Field Laboratory).

DownLoad: Full-Size Img PowerPoint

图 3 武汉强磁场中心转角样品杆　(a)机械结构图; (b) 转角示意图; (c) 角度标定原理图

Figure 3. Rotation sample rod in WHMFC (Wuhan National High Magnetic Field Center): (a) Mechanical structure diagram; (b) situation at different angles; (c) principle of angle calibration.

DownLoad: Full-Size Img PowerPoint

图 4 转角样品测量杆实物图　(a) 杆件顶部旋钮及引线罗盘; (b) 底部样品台正面; (c) 底部样品台背面

Figure 4. Physical diagram rotation sample rod: (a) Top part; (b) the front of the bottom sample stage; (c) the back of the bottom sample stage.

DownLoad: Full-Size Img PowerPoint

图 5 60 T脉冲强磁场下转角电输运实验相关数据处理过程

Figure 5. Signal processing of angular-dependent electrical transport experiment in 60 T pulsed high magnetic field.

DownLoad: Full-Size Img PowerPoint

图 6 Cd₃As₂三维嵌套各向异性费米面构造图　(a) 不同晶轴方向的费米面最大横截面; (b) B_[112]方向上的量子振荡

Figure 6. 3D nested anisotropic Fermi surface construction of Cd₃As₂: (a) Largest cross section of Fermi surface versus the magnetic field orientation; (b) quantum oscillation for B_[112] direction.

DownLoad: Full-Size Img PowerPoint

图 7 拓扑绝缘体Bi₂Se₃二维表面态特征　(a) 量子振荡现象^[31]; (b) 振荡频率随转角的变化曲线^[32]

Figure 7. 2D surface state of a topological insulator Bi₂Se₃: (a) Quantum oscillation^[31]; (b) frequency of the oscillations as a function of θ ^[32].

DownLoad: Full-Size Img PowerPoint

图 8 脉冲强磁场下的半金属材料量子极限输运研究　(a) TaP; (b) Bi

Figure 8. Quantum limit electrical transport of semi-metal materials in pulsed high magnetic fields: (a) TaP; (b) Bi.

DownLoad: Full-Size Img PowerPoint

图 9 超导材料K₂Cr₃As₃的转角电输运实验结果　(a) π/2处出现上方临界场(H_c2)的最大值表明了泡利极限的缺失; (b) 极坐标图则体现了H_c2的三重调制性

Figure 9. Electrical transport of the superconducting material K₂Cr₃As₃: (a) The maximum value of the upper critical field (H_c2) at π/2 indicates the absence the Pauli paramagnetic effect; (b) the polar map of H_c2 shows a unique three fold modulation.

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表 1 不同样品杆技术参数比较

Table 1. Technical parameters of different kind of measurement rod.

样品杆类型及参数	角度范围θ/(°)	角度分辨率θ/(°)	磁场范围B/T	适应孔径d/mm	样品台空间
PPMS商用样品杆	–10—370	0.05	± 16 (稳态)	25	相对孔径较大
传统拉绳式样品杆	0—180	1.00	> 60 (脉冲)	9	相对孔径较小
新型拉杆式样品杆	–5—185	0.10	> 60 (脉冲)	8	相对孔径较大

DownLoad: CSV

[1]	Li G, Xiang Z, Yu F, Asaba T, Lawson B, Cai1 P, Tinsman C, Berkley A, Wolgast S, Eo Y S, Kim D J, Kurdak C, Allen J W, Sun K, Chen X H, Wang Y Y, Fisk Z, Li L 2014 Science 346 1208 Google Scholar
[2]	Huang X C, Zhao L X, Long Y J, Wang P P, Chen D, Yang Z H, Liang H, Xue M Q, Wen H M, Fang Z, Dai X, Chen G F 2015 Phys. Rev. X 5 031023 Google Scholar
[3]	Wang Y J, Yu J H, Wang Y Q, Xi C Y, Ling L S, Zhang S L, Wang J R, Xiong Y M, Han T, Han H, Yang J, Gong J X, Luo L, Tong W, Zhang L, Qu Z, Han Y Y, Zhu W K, Pi L, Wan X G, Zhang C J, Zhang Y H 2018 Phys. Rev. B 97 115133 Google Scholar
[4]	Ramshaw B J, Vignolle B, Day J, Liang R X, Hardy W N, Proust C, Bonn D A 2011 Nature Phys. 7 234 Google Scholar
[5]	Sebastian S E, Harrison N, Altarawneh M M, Liang R X, Bonn D A, Hardy W N, Lonzarich G 2011 Nat. Commun. 2 471 Google Scholar
[6]	Murphy J, Tanatar M A, Graf D, Brooks J S, Bud’ko S L, Canfield P C, Kogan V G, Prozorov R 2013 Phys. Rev. B 87 094505 Google Scholar
[7]	Qu D X, Hor Y S, Xiong J, Cava R J 2010 Science 329 821 Google Scholar
[8]	Quantun Design PPMS Specification https://www.qdusa.Com/sitedocs/productBrochures/1070-002.pdf [2019-7-12]
[9]	Doan N N, James M, Chuck H M 2016 IEEE Trans. Appl. Supercond. 26 4300905 Google Scholar
[10]	Fritz H, Miura N 2003 Magnetic Fields Science and Technology (Vol. 1) (New Jersey: World Scientific Publishing) pp285−316
[11]	Han X T, Peng T, Ding H F, Ding T H, Zhu Z W, Xia Z C, Wang J F, Han J B, Ouyang Z W, Han Y B, Xiao H X, Cao Q L, Lü Y L, Pan Y, Li L 2017 Matter and Radiation at Extremes 2 278 Google Scholar
[12]	王绍良, 李亮, 欧阳钟文, 夏正才, 夏念明, 彭涛, 张凯波 2012 物理学报 61 107601 Google Scholar Wang S L, Li L, Ouyang Z W, Xia Z C, Xia N M, Peng T, Zhang K B 2012 Acta Phys. Sin. 61 107601 Google Scholar
[13]	Li L, Lü Y L, Xiao H X, Pan Y, Peng T 2016 IEEE Trans. Appl. Supercond. 26 4303204 Google Scholar
[14]	刘永杰, 林梓泉, 王俊峰 2016 物理 45 19 Google Scholar Liu Y J, Lin Z Q, Wang J F 2016 Physics 45 19 Google Scholar
[15]	Cheng K Q, Wang L, Xu Y J, Yang F, Zhu H P, Ke J Z, Lu X F, Xia Z C, Wang J F, Shi Y G, Yang Y F, Luo Y K 2019 Phys. Rev. Mater. 3 021402(R)Google Scholar
[16]	Wang H C, Liu H W, Li Y N, Liu Y J, Wang J F, Liu J, Dai J Y, Wang Y, Li L, Yan J Q, Mandrus D, Xie X C, Wang J 2018 Sci. Adv. 4 5096 Google Scholar
[17]	Zhao L X, Xu L C, Zuo H K, Wu X M, Gao G Y, Zhu Z W 2018 Phys. Rev. B 98 085137 Google Scholar
[18]	Shi J T, Han X T, Xie J F, Li L 2016 IEEE Trans. Appl. Supercond. 26 4300604 Google Scholar
[19]	Zuo H K, Xia Z C, Li L 2014 CN Patent for Utility Model 203704948 U
[20]	Coldea A I, Andrew C M J, Analytis J G, McDonald R D, Bangure A F, Chu J H, Fisher I R, Canrrinton A 2009 Phys. Rev. Lett. 103 026404 Google Scholar
[21]	Torque Magnetometry in Pulsed Fields, National High Magnetic Field Laboratory https://nationalmaglab.Org/user-facilities/pulsed-field-facility/pff-measurement-techniques/torque-magnetometry-pff [2019-7-12]
[22]	Wang K F, Graf D, Lei H C, Tozer S W, Petrovic C 2011 Phys. Rev. B 84 220401 Google Scholar
[23]	Wang K F, Graf D, Wang L M, Lei H C, Tozer S W, Petrovic C 2012 Phys. Rev. B 85 041101 Google Scholar
[24]	Liu Q Y, Zhang S Z, Ding L C, Zuo H K, Han X T 2019 IEEE International Instrumentation and Measurement Technology Conference Proceedings Auckland, New Zealand, May 20–23, 2019 p504
[25]	Zhao Y F, Liu H W, Zhang C L, Wang H C, Wang J F, Lin Z Q, Xing Y, Lu H, Liu J, Wang Y, Brombosz S M, Xiao Z L, Jia S, Xie X C, Wang J 2015 Phys. Rev. X 5 031037 Google Scholar
[26]	Gotze K, Klotz J, Gnida D, Harima H, Aoki D, Demuer A, Elgazzar S, Wosnitza J, Kaxzorowski D, Sheikin I 2015 Phys. Rev. B 92 115141 Google Scholar
[27]	Arnold F, Shekhar C, Wu S C, Sun Y, Reis R D, Kumar N, Naumann M, Ajeesh M O, Schmidt M, Grushin A G, Bardarson J H, Baenitz M, Sokolov D, Borrmann H, Nicklas M, Felser C, Hassinger E, Yan B H 2016 Nat. Commun. 7 11615 Google Scholar
[28]	Zhang C L, Schindler F, Liu H W, Chang T R, Xu S Y, Chang G Q, Hua W, Jiang H, Yuan Z J, Sun J L, Jeng H T, Lu H Z, Lin H, Hasan M Z, Xie X C, Nerpert T, Jia S 2017 Phys. Rev. B 96 165148 Google Scholar
[29]	Kim H, Wang K F, Nakajima Y, Hu R W, Ziemak S, Syers P, Wang L M, Hodovanets H, Denlinger J D, Brydon P M, Agterberg D F, Tanatar M A, Prozorov R, Paglione J 2018 Sci. Adv. 4 4513 Google Scholar
[30]	Zhu Z W, Lin X, Liu J, Fauque B, Tao Q, Yang C L, Shi Y G, Behnia K 2015 Phys. Rev. Lett. 114 176601 Google Scholar
[31]	Analytis J G, McDonald R D, Riggs S C, Chu J H, Boebinger G S, Fisher L R 2010 Nature Phys. 6 960 Google Scholar
[32]	Petrushevsky M, Lahoud E, Ron A, Maniv E, Diamant I, Neder I, Wiedmann S, Guduru V K, Chiappini F, Zeitler U, Maan J C, Chashka K, Kanigel A, Dagan Y 2012 Phys. Rev. B 86 045131 Google Scholar
[33]	Zhang C L, Xu S Y, Wang C M, Lin Z Q, Du Z Z, Guo C, Lee C C, Lu H, Feng Y Y, Huang S M, Chang G Q, Hsu C H, Liu H W, Li L, Zhang C, Zhang J L, Xie X C, Neupert T, Hasan M Z, Lu H Z, Wang J F, Jia S 2017 Nature Phys. 13 979 Google Scholar
[34]	Fauque B, Yang H, Sheikin I, Balicas L, Issi J P, Behnia K 2009 Phys. Rev. B 79 245124 Google Scholar
[35]	Fauque B, Vignolle B, Proust C, Issi J P, Behnia K 2009 New J. Phys. 11 113012 Google Scholar
[36]	Zuo H K, Bao J K, Liu Y, Wang J H, Jin Z, Xia Z C, Li L, Xu Z, Kang J, Zhu Z W, Cao G H 2017 Phys. Rev. B 95 014502 Google Scholar

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