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Abstract

Superconducting quantum interference device (SQUID) has extremely high magnetic field sensitivity, current sensitivity, and can detect a low-noise weak current signal. The SQUID current sensor has become the only option of the readout of low-noise detector, such as transition-edge sensor (TES). In this paper, a second-order gradiometric cross-coupled SQUID current sensor for TES application is developed. According to the requirements for TES detectors, the structure and various parameters of SQUID current sensor are designed. The SQUID loop, input coil and feedback coil of the SQUID current sensor all use the second-order gradiometric structure. All the couple ways between SQUID loop and input coil or feedback coil adopt cross-coupling mode in different planes, which can effectively weaken the parasitic capacitance. A second-order gradiometric cross-coupled SQUID current sensor based on Nb/Al-AlO _x/Nb Josephson junction is successfully fabricated on a silicon wafer by optimizing the process. The properties of the second-order gradiometric cross-coupled SQUID current sensor are measured at liquid helium temperature. The bias current of SQUID is 215 μA when the modulation depth of V- Φmodulation curve is maximum. The maximum modulation peak of SQUID is 31 μV. The flux-to-voltage transfer coefficient of SQUID is 108 μV/ Φ ₀. The input coil current sensitivity is 17 μA/ Φ ₀, the mutual inductance between SQUID loop and input coil is 117 pH. The current sensitivity of feedback coil is 86 μA/ Φ ₀, the mutual inductance between SQUID loop and feedback coil is 23 pH. The second-order gradiometric cross-coupled SQUID current sensor has a white flux noise of 2 μ Φ ₀/ $ \sqrt{{\rm{H}}{\rm{z}}} $ and a white current noise of 34 pA/ $ \sqrt{{\rm{H}}{\rm{z}}} $ with 1/ fcorner frequency around 200 Hz. The result of noise level under the condition without magnetic shielding shows that the SQUID current sensor with second-order gradiometric cross-coupled structure has an excellent capability of weakening the environmental electromagnetic interference. In the future, we will further improve the mutual inductance of the second-order gradiometric cross-coupled SQUID current sensor between SQUID loop and input coil, optimize the size and critical current of Josephson junction, in order to improve the input sensitivity of SQUID device, reduce the current noise level and the 1/ fcorner frequency, and meet more requirements for TES applications.

Keywords:

superconducting quantum interference device/
transition-edge sensor/
flux noise/
current noise/
current sensitivity

Authors and contacts

Corresponding author:Zhong Qing,zhongq@nim.ac.cn; Li Jin-Jin,jinjinli@nim.ac.cn;

Funds:Project supported by the National Key R&D Program of China (Grant No. 2017YFF0206105), the National Natural Science Foundation of China (Grant Nos. 61701470, 20161361354), and the National Institute of Metrology China (Grant Nos. AKY1946, AKYZD2012)

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参数	设计值
约瑟夫森结尺寸S/(µm × µm)	7 × 7
约瑟夫森结临界电流I₀/µA	49
约瑟夫森结电容C_J/pF	2
并联电阻R_sh/Ω	0.84
回滞系数β_c	0.2
调制系数β_L	1.6
SQUID环路电感L_SQ/pH	33
SQUID环路与输入线圈互感M_IN/pH	130
SQUID环路与反馈线圈互感M_FB/pH	36
输入线圈电感L_IN/nH	3
反馈线圈电感L_FB/nH	1
输入电流灵敏度1/M_IN/(μA·Φ₀^–1)	15
反馈电流灵敏度1/M_FB/(μA·Φ₀^–1)	56

DownLoad: CSV

参数	实测值
偏置电流I_{b, max}/μA	215
并联电阻R_sh/Ω	1
回滞系数β_c	0.67
输入电流灵敏度1/M_IN/(μA·Φ₀^–1)	17
反馈电流灵敏度1/M_FB/(μA·Φ₀^–1)	86
磁通-电压转换系数V_Φ/(μV·Φ₀^–1)	108
最大调制峰值V_pp/μV	31
磁通白噪声$\sqrt{S_{\varPhi}} $/(μΦ₀·$ \sqrt{{\rm{H}}{\rm{z}}} $^–1)	2
电流白噪声$\sqrt{S_I} $/(pA·$ \sqrt{{\rm{H}}{\rm{z}}} $^–1)	34
SQUID环路与输入线圈互感M_IN/pH	117
SQUID环路与反馈线圈互感M_FB/pH	24

DownLoad: CSV

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Vol. 70, Issue 12 - 2021-06-20

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