主要研究成果

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主要研究成果

1. J Li, Z F Liu, Y Ma, et al. Seismic noise effect suppression for the performance testing of high-precision space electrostatic accelerometers using a torsion pendulum with differential configuration. Measurement Science and Technology, 2024, 35(11), 115105.

2. H M Wang, L Cai, Z Y Shen, et al. Removing spikes in TianQin-1 inertial sensor data using machine learning method. Measurement Science and Technology, 2024, 35(10), 105114.

3. Guilin Li, Jun Ke, Honggang Li, et al. Thermal induced noise on test mass with copper alloy electrode housing for spaceborne gravitational wave detection. PHYSICAL REVIEW D, 2024, 109, 082001.

4. Honggang Li, Guilin Li, Wei Hong, et al. Capacitive Sensing-Based Charge Measurement for Space Inertial Sensors. IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 2024, 73, 6501509.

5. Menghao Zhao, Wei Hong, Chunyu Xiao, et al. High-precision ground simulator for laser tracking of gravity satellite. REVIEW OF SCIENTIFIC INSTRUMENTS, 2024, 92(2), 024503.

6. Bingxue Chen, Wei Hong, Honggang Li, et al. Using finite element simulation to evaluate charge measurement precision for space inertial sensors. MEASUREMENT SCIENCE AND TECHNOLOGY, 2024, 35(4), 045026.

7. Chi Lei, Wei Su, Wei Hong, et al. Simulation for the test mass charging rate in the Tianqin orbit. CLASSICAL AND QUANTUM GRAVITY, 2024, 41(2), 025001.

8. Yun Ma, Yan-Zheng Bai, Hong-Yin Li, Ze-Bing Zhou, Zheng Zhou, Identification and compensation of quadratic terms of a space electrostatic accelerometer, Rev. Sci. Instrument 89 (2018) 114502.

9.李洪银,屈少波,白彦峥,吴书朝,周泽兵,静电悬浮加速度计在轨质心位置的最小二乘估计,地球物理学报 60(3) (2017) 897-902.

10. Yanzheng Bai, Zhuxi Li, Ming Hu, Li Liu, Shaobo Qu, Dingyin Tan, Haibo Tu, Shuchao Wu, Hang Yin, Hongyin Li, Zebing ZhouResearch and Development of Electrostatic Accelerometer In HUST for Space Science missions, Sensors 17 (2017) 1943.

11. Jun Luo, Li-Sheng Chen, Hui-Zong Duan, Yun-Gui Gong, Shoucun Hu, Jianghui, Qi Liu, Jianwei Mei, Vadim Milyukov, Mikhail Sazhin, Cheng-Gang Shao, Viktor T. Toth, Hai-Bo Tu, Yamin Wang, Yan Wang, Hsien-Chi Yeh, Ming-Sheng Zhan, Yonghe Zhang, Vladimir Zharov, Ze-Bing Zhou, TianQin: a space-borne gravitational wave detector, Class. Quantum Grav. 332016035010-1-19.

12. Shao-Bo Qu, Xiao-Mei Xia, Yan-Zheng Bai, Shu-Chao Wu, Ze-Bing Zhou, Self-calibration method of the bias of a space electrostatic accelerometer, Rev. Sci. Instrum. 87 (2016) 224502.

13. Yan-Zheng Bai, Le Fang, Jun Luo, Hang Yin, Ze-Bing Zhou, Improving the angular deflection sensitivity of a torsion pendulum by an electrostatic spring, Class. Quantum Grav. 32(17) (2015) 175018.

14. Tan Ding-Yin, Yin Hang, Zhou Ze-Bing, Seismic noise Suppression for Ground-based Investigation of an Inertial Sensor by Suspending the Electrode Cage, Chin. Phys. Lett. 32(9) (2015) 090401.

15. L. Liu, X. Ye, S.C. Wu, Y.Z. Bai, Z.B. Zhou, A low-frequency vibration insensitive pendulum bench based on translation-tilt-compensation for measuring the performances of inertial sensor, Class. Quantum Grav. 32 (2015), 195016.

16. M. Hu, Y.Z. Bai, Z.B. Zhou, Z.X. Li, J Luo, Resonant frequency detection and adjustment method for a capacitive transducer with differential transformer bridge, Rev. Sci. Instrum. 85(5) (2014) 055001.

17. Hang Yin, Yan-Zheng Bai, Ming Hu, Li Liu, Jun Luo, Ding-Yin Tan, Hsien-Chi Yeh, Ze-Bing Zhou, Measurements of temporal and spatial variation of surface potential using a torsion pendulum and a scanning conducting probe, Phys. Rev. D 90(2014) 122001.

18. G. Li, S. C. Wu, Z. B. Zhou, Y. Z. Bai, M. Hu, and J. Luo, Design and validation of a high-voltage levitation circuit for electrostatic accelerometers, Rev. Sci. Instrum. 84(12) (2013) 125004.

19. Wei Tian, Shu-Chao Wu Ze-bing Zhou, Shao-Bo Qu, Yan-Zheng Bai, and Jun LuoHigh resolution space quartz-flexure accelerometer based on capacitive sensing and electrostatic control technology, Rev. Sci. Instrum. 83(2012) 095002.

20. L. Liu, Y. Z. Bai, Z. B. Zhou, H. Yin, D. Y. Tan and J. LuoMeasurement of the effect of a thin discharging wire for an electrostatic inertial sensor using a high quality factor pendulum, Class. Quantum Grav. 29 (2012) 055010.

21. Z B Zhou, L Liu, H B Tu, Y Z Bai, J Luo, Seismic noise limit for ground-based performance measurements of an inertial sensor using a torsion balance, Class. Quantum Grav. 27 (2010) 175012.

22. H B Tu, Y Z Bai, Z B Zhou, L Liu, L Cai, and J Luo, Performance measurements of an inertial sensor with a two-stage controlled torsion pendulum, Class Quantum. Grav. 27 (2010) 205016.

23. Z B Zhou, S W Gao and J Luo, Torsion pendulum for the performance test of the inertial sensor for ASTROD-I, Class. Quantum Grav. 22 (2005) S537S542.

24. Z.B. Zhou, J. Luo, Q. Yan, Z.G. Wu, Y.Z. Zhang, and Y.X. Nie, New upper limit from terrestrial equivalence principle test for extended rotating bodies, Phys. Rev. D 66 (2002) 022002.

25. J. Luo, Y.X. Nie, Y.Z. Zhang, and Z.B. Zhou, Null result for violation of the equivalence principle with free-fall rotating gyroscopes, Phys. Rev. D 65 (2002) 042005.

26. Z.B. Zhou, J. Winterflood, L. Ju, D.G. Blair, Investigation of a laser walk-off angle sensor and its application to tilt measurement in gravitational wave detectors, Phys. Lett. A 280 (2001) 197-203.

27. Z.B. Zhou, S.H. Fan, F. Long, and J. Luo, Improved low frequency seismic noise isolation system for gravitational wave detectors, Rev. Sci. Instrum. 69 (1998) 2781-2784.