LUO Jie

Editor:Date:2023-09-19ClickTimes:


 

 

 

LUO Jie

Sex:

Male

Political status:

CPC member

Nationality:

Han

Qualification and degree:

Graduate, PhD

Graduated from::

China University of Geosciences (Wuhan)

Title:

Professor, doctoral supervisor

 

 

Main experiences

2009.11-2012.05: postdoctoral at School of Physics, Huazhong University of Science and Technology

2006.09-2009.06: PhD in engineering, Geo-exploration and Information Technology, China University of Geosciences (Wuhan)

2003.09-2006.06: master’s degree in engineering, Computer Application Technology, China University of Geosciences (Wuhan)

Research fields

Noise analysis and modeling simulation of inertial sensor, experiment data processing and weak signal detection in gravitational wave detection

Courses offered

Signal and system, fundamentals of information processing, error analysis and data processing

Contact information

Office: Room 511, No. 2 Teaching Building

Email: luojiethanks@126.com  QQ: 710940102

Brief introduction to the research group

The research fields of the research group include noise analysis and modeling simulation of inertial sensor, experimental data processing and weak signal detection in gravitational wave detection, supported by the Center for Gravitational Experiment, Huazhong University of Science and Technology (national major scientific and technological infrastructure for precise gravity measurement) and TianQin Research Center for Gravitational Physics, Sun Yat-sen University. The research group is well funded, and was granted one project under the National Key Research and Development Program in 2020 and one subproject under the National Key Research and Development Program in 2022. At present, the gravitational wave detection simulation laboratory is under construction. We recruit a certain number of master and doctoral students every year. Welcome undergraduates and postgraduates who are interested in scientific research and have certain computing and programming ability.

Scientific research programs

  1. Project supported by National Key Research and Development Program (2020YFC2200501): Disturbing force analysis of inertial sensor and establishment of index system (PI; under study; fund: 3,820,000Yuan);

  2. Subproject supported by National Key Research and Development Program (2022YFC2204602): Study on the data processing method for suppressing laser frequency noise and clock noise based on time-delay interference (PI; under study; fund: 1,150,000Yuan);

  3. Development of in-orbit disturbing force simulation and demonstration system for accelerometer (PI; under study; fund: 1,000,000Yuan);

  4. Accelerometer disturbing force simulation system (PI; under study; fund: 300,000Yuan);

  5. Development of electromagnetic signal monitoring and electromagnetic data identification software (PI; under study; fund: 489,900Yuan);

  6. General Program of National Natural Science Foundation of China (11575160): Methods Study on the Noise Analysis and Weak Signal Extraction in the Weak Equivalence Principle of Quartz Fiber Torsion Balance Test with High Qs (PI; concluded);

  7. General Program of National Natural Science Foundation of China (11175160): Research on the noise analysis and data processing method in angular acceleration G measurement experiment (PI; concluded);

  8. National “973” subproject (2010CB832801): Accurate measurement of gravitation constant G (PI; concluded);

  9. Key program of the Foundation of Hubei Province (2013CFA045): Research on the influence of micro earthquake on periodic extraction accuracy of torsion balance (PI; concluded);

  10. General program of the Foundation of Hubei Province ((2010CDB04102): Research on the impact of thermal noise and related factors on periodic extraction accuracy of torsion balance (PI; concluded);

  11. National Natural Science Foundation of China for Instruments (10927505): Research on the key technology and experimental equipment for measuring the gravitational constant G by angular acceleration method (participant; concluded);

Research awards

Title of award-winning project: Accurate measurement of the gravitational constant G; Award level: Grand Prize for Science and Technology Progress of Hubei Province; Year of the award: 2023; Ranking of the unit: third participant; Personal ranking: 10/23.

Student training

  • Ke Jun, a doctoral student of Grade 2020, published 5 SCI papers and won the National Scholarship for Doctoral Students.

  • Lei Yang, a postgraduate student of Grade 2017, published 1 SCI paper.

  • Dong Tao, a postgraduate student of Grade 2017, published 1 SCI paper.

  • Shen Liangcheng, a postgraduate of Grade 2016, published on SCI paper.

  • Xu Jiahao, a postgraduate of Grade 2015, published 2 SCI papers and won the national scholarship and school-level excellent master thesis.

  • Wu Weihuang, a postgraduate of Grade 2014, published 4 SCI papers, and won the national scholarship and school-level excellent master thesis

  • Zhan Wenze, a postgraduate of Grade 2014, published 2 SCI papers.

  • Tian Yuan, a postgraduate of Grade 2012, published 3 SCI papers and won the national scholarship

Selected papers

  1. Jun Ke, Dong W C, Huang S H, Tan Y J, Tan W H, Yang S Q, Shao C G, and Jie Luo. Electrostatic effect due to patch potentials between closely spaced surfaces. Phys. Rev. D., 2023, 107: 065009 [Indexed by SCI].

  2. Zhao Y L, Tan Y J, Wu W H, Luo J, and Shao C G. Constraining the Symmetron Model with the HUST-2020 Torsion Pendulum Experiment. Phys. Rev. Lett., 2022, 129: 141101 [Indexed by SCI].

  3. Jun Ke, Jie Luo, Tan Y J, et al. Non-isothermal squeeze film damping in the test of gravitational inverse-square law [J]. Classical and Quantum Gravity, 2022, 39(11): 115004 [Indexed by SCI].

  4. Wu H, Jun Ke, Wang P P, Jie Luo, et al. Arm locking using laser frequency comb [J]. Optics Express, 2022, 30(5): 8027-8048 [Indexed by SCI].

  5. Jun Ke, Jie Luo, Shao C G, et al., Combined Test of the Gravitational Inverse-Square Law at the Centimeter Range. Phys. Rev. Lett., 2021, 126: 211101 [Indexed by SCI].

  6. Jie Luo, Yang Lei, Cheng-gang Shao, Jian-ping Liu, Dong Li, Rui-qi Liu, and Qing Li. Scheme of G measurement with large amplitude torsion pendulum. PHYSICAL REVIEW D, 2020 [Indexed by SCI].

  7. Jun Ke, Jie Luo, Yu-Jie Tan and Cheng-Gang Shao. Influence of the residual gas damping noise in the test of the gravitational inverse-square law. Classical and Quantum Gravity, 2020 [Indexed by SCI].

  8. ie Luo, Jun Ke, Yi-Chuan Liu, Xiang-Li Zhang, Wei-Ming Yin, and Cheng-Gang Shao. Optimal estimation of the amplitude of signal with known frequency in the presence of thermal noise. Chin. Phys. B, 2019 [Indexed by SCI].

  9. Jie Luo, Tao Dong, Cheng-Gang Shao, Yu-Jie Tan, and Hui-Jie Zhang. Influence of the Earth’s rotation on measurement of gravitational constant G with the time-of-swing method. Chin. Phys. B, 2019 [Indexed by SCI].

  10. Jie Luo, Liang-Cheng Shen, Cheng-Gang Shao*, Qi Liu*, and Hui-Jie Zhang. Correlation method estimation of the modulation signal in the weak equivalence principle test. Chin. Phys. B, 2018 [Indexed by SCI].

  11. Wen-Ze Zhan, Jie Luo, Cheng-Gang Shao, Di Zheng, Wei-Ming Yin, and Dian-Hong Wang. Determination of the thermal noise limit in test of weak equivalence principle with a rotating torsion pendulum. Chin. Phys. B, 2017 [Indexed by SCI].

  12. Jie Luo, Jia-Hao Xu, Qi Liu, Cheng-Gang Shao, Lin Zhu, Hui-Hui Zhao, and Wei-Huang Wu. An improved torque type gravity gradiometer with dynamic modulation. Acta Geod Geophys, 2017 [Indexed by SCI].

  13. Jia-Hao Xu, Cheng-Gang Shao, Jie Luo, Qi Liu, Lin Zhu, and Hui-Hui Zhao. Effect of gravity gradient in weak equivalence principle test. Chin. Phys. B, 2017 [Indexed by SCI].

  14. Wei-Huang Wu, Yuan Tian, Chao Xue, Jie Luo, Cheng-Gang Shao. Correction of cosine oscillation to the improved correlation method of estimating the amplitude of gravitational background signal. Chin. Phys. B, 2017 [Indexed by SCI].

  15. Wei-Huang Wu, Yuan Tian, Jie Luo, Cheng-Gang Shao, Jia-Hao Xu, and Dian-Hong Wang. An improved correlation method for amplitude estimation of gravitational background signal with time-varying frequency. Rev Sci Instrum, 2016 [Indexed by SCI].

  16. Jie Luo, Wen-Ze Zhan, Wei-Huang Wu, Cheng-Gang Shao, and Dian-Hong Wang. Influence of the colored noise on determining the period of a torsion pendulum. Chin. Phys. B, 2016 [Indexed by SCI].

  17. Jie Luo, Wei-Huang Wu, Chao Xue, Cheng-Gang Shao, Wen-Ze Zhan, Jun-Fei Wu, and Vadim Milyukov. Influence of tungsten fiber’s slow drift on the measurement of G with angular acceleration method. Rev Sci Instrum, 2016 [Indexed by SCI].

  18. Jie Luo, Yuan Tian, Dian-Hong Wang, Cheng-Gang Qin, Cheng-Gang Shao. Measurement of the PPN parameter γ by testing the geometry of near-Earth space. Gen Relativ Gravit, 2016 [Indexed by SCI].

  19. Jie Luo, Wei-Huang Wu, Cheng-Gang Shao, Qing-Li, Jian-Ping Liu, Wen-Ze Zhan and Dian-Hong Wang. Influence of temperature on period of torsion pendulum with a high-Q fused silica fiber. Rev Sci Instrum, 2015 [Indexed by SCI].

  20. Luo Jie, Tian Yuan, Shao Cheng-Gang, and Wang Dian-Hong. Influence of the environmental noise on determining the period of a torsion pendulum. Chin. Phys. B, 2015 [Indexed by SCI].

  21. Jie Luo, Yuan Tian, Dian-Hong Wang and Cheng-Gang Shao. Uncertainty due to quantization error in measurement of Newton’s constant with the angular acceleration method. Meas. Sci. Technol, 2014 [Indexed by SCI].

  22. Jie Luo, Cheng-Gang Shao, Yuan Tian and Dian-Hong Wang. Thermal noise limit in measuring the gravitational constant G using the angular acceleration method and the dynamic deflection method. Phys Lett A, 2013 [Indexed by SCI].

  23. Luo Jie, Shao Cheng-Gang, Wang Dian-Hong, Tian Yuan. Influence of the Earth's rotation on the measurement of Newton's constant G with angular acceleration method. Chin Phys Lett, 2012 [Indexed by SCI].

  24. Jie Luo, Cheng-Gang Shao and Dian-Hong Wang. Thermal noise limit on the period of a torsion pendulum. Class. Quantum Grav, 2009 [Indexed by SCI].

  25. Jie Luo, Dian-Hong Wang. An improved correlation method for determining the period of a torsion pendulum. Rev Sci Instrum, 2008 [Indexed by SCI].

  26. Dian-Hong Wang, Jie Luo, Kai Luo. Precise determination of the amplitude of signal with known frequency based on correlated noise model. Rev Sci Instrum, 2006 [Indexed by SCI].

  27. Luo Jie, Wang Dian Hong, Liu Qi , Shao Cheng Gang. Precise determination of the period of a torsion pendulum in measurement of gravitational constant G. Chin Phys Lett, 2005 [Indexed by SCI].