People

WANG Lirong

Job Title: Professor

School/Institute:State Key Lab of Quantum Optics and Quantum Optics Devices, Institute of Laser Spectroscopy, Shanxi University, Taiyuan.

E-mail: wlr@sxu.edu.cn

Tel: +86-0351-7018927

Biography

WANG Lirong is a professor and doctoral advisor at State Key Laboratory of Quantum Optics and Quantum Optics Devices, Institute of Laser Spectroscopy, Shanxi University. She has selected as a distinguished professor of Young Sanjin Scholar Support Program of the Shanxi Province in 2016. She won the first prize of the Technological Invention Award of Shanxi Province Science and Technology Award twice (the second winner and the fourth winner). She has presided over 10 funds, including the national and provincial funds. In the recent five years, she has published 37 SCI-cited papers written as corresponding author.

Education:

[1] 2004.09 to 2008.07, Doctor of Science, Atomic and Molecular Physics, State key laboratory of quantum optics and quantum optics devices, College of physics and electronic engineering, Shanxi university.

[2] 1999.09 to 2010.07, Maser of Science, Optics, State Key Laboratory of Quantum Optics and Quantum Optics Devices, College of Physics and Electronic Engineering, Shanxi University.

[3] 1990.09 to 1994.07, Bachelor of Science, Physics, College of Physics and Electronic Engineering, Shanxi University.

Research Area:

[1] Atomic and molecular precision spectroscopy

[2] Quantum coherence effects in atomic and molecular systems

Employment:

[4] 2015.12-Now, Institute of Laser Spectroscopy, Shanxi University, Professor

[3] 2008.10-2015.12, Institute of Laser Spectroscopy, Shanxi University, Associate Professor

[2] 2002.07-2008.10, College of Physics and Electronic Engineering, Shanxi University, Lecturer

[1] 1994. 12-1999.9, Jinzhong University, Assistant Professor

Grants and Projects:

[4] The National Natural Science Foundation of ChinaHigh-sensitivty Measurment of Electron-to-proton Mass Ratio Variation Based on Ultracold Molecules”, Grant No. 61875112, 2019/01-2022/12.

[3] The National Natural Science Foundation of ChinaCoherent control of ultracold molecules and precision measurement of relevant physical constants”, Grant No. 61575116, 2016/01-2019/12.

[2] The National Natural Science Foundation of China Research on High-precision Frequency Comb Spectroscopy of Ultracold Atoms and Molecules”, Grant No. 61378049, 2014/01-2017/12.

[1] The National Natural Science Foundation of China “Controlling ultracold cesium molecules using the optical induced Feshbach resonance and spectrscopy measurement”, Grant No. 60978001, 2010/01-2012/12.

Selective Publications

1. Accessing the spectrum of a single-photon by the Hong-Ou-Mandel interference, Lifeng Duan, Aojie Xu, Lirong Wang†, and Yun Zhang†, Optics Express,32(4), 5418-5428 (2024)

2. Generation of 160 nm vacuum ultraviolet light at 82 MHz in a KBBF crystal by Fifth-harmonic of a Ti:sapphire laser, Yun Zhang, Lirong Wang, Chinese Optics Letters22(5), 051901(2024)

3. Manuscript Title: Nonlinear frequency up-conversion of perfect vortex beams based on four wave-mixing in 85Rb atomsMaolin Zhang, Xuewen Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Communications,557,130343 (2024)

4. A Rydberg atom-based amplitude-modulated receiver using the dual-tone microwave field, Jinpeng Yuan*, Ting jin, Yang Yan, Liantuan Xiao, Suotang Jia, Lirong Wang†, EPJ Quantum Technology, 11:2, (2024)

5. A Rydberg atom-based receiver with amplitude modulation technique for the fifth-generation millimeter-wave wireless communication, Jinpeng Yuan, Ting jin, Liantuan Xiao, Suotang Jia, Lirong Wang†, IEEE Antennas and Wireless Propagation Letters, 22(10), 2580-2584 (2023)

6. Three-dimensional location system based on an L-shaped array of Rydberg atomic receiversYang Yan, Jinpeng Yuan*, Linjie Zhang, Liantuanxiao, Suotang Jia and Lirong Wang†, Optics Letters, 48(15), 3945-3948 (2023)

7. Photonic graphene with reconfigurable geometric structures in coherent atomic ensembles, Fuqiang Niu, Heifei Zhang, Jinpeng Yuan+, Liantuan Xiao, Suotang Jia, and Lirong Wang†, Frontiers of Physics, 18(5), 52304 (2023)

8. Identification of orbital angular momentum using atom-based spatial self-phase modulationWei Gao, Sandan Wang, Jinpeng Yuan+, Liantuan Xiao, Suotang Jia, and Lirong Wang†, Optics Express, 31(9), 13528-13535 (2023)

9. Geometric pattern evolution of photonic graphene in coherent atomic mediumHengfei Zhang, Jinpeng Yuan+, Chaohua Wu, , Liantuanxiao, Suotang Jia, and Lirong Wang*, Optics Express, 31(7), 11335-11343 (2023)

10. Characterization of two-photon interference between a weak coherent state and a heralded single photon state, Aojie Xu, Lifeng Duan, Lirong Wang†, and Yun Zhang†, Optics Express, 31(4), 5662-5669 (2023)

11. Creation and Control of Vortex-Beam Arrays in Atomic VaporJinpeng Yuan, Hengfei Zhang, Chaohua Wu, Gang Chen,* Lirong Wang,* Liantuan Xiao, and Suotang JiaLaser & Photonics Reviews, 17(5), 2200667 (2023)

12. Manipulation of the orbital angular momentum via four-wave mixing in Rb vapor, Ning Liu, Jinpeng Yuan+, Liantuan Xiao, Suotang Jia and Lirong Wang†, Laser Physics Letters, 20, 035204 (2023)

13. Identification of orbital angular momentum using atom-based spatial self-phase modulationXuewen Wang, Jinpeng Yuan, , Liantuanxiao, Suotang Jia and Lirong Wang*,Optics Letters, 48(2), 303-306 (2023)

14. All-optical information conversion in Rb vapor based on spatial cross-phase modulationSandan Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Express, 30(25), 45517-45524 (2022)

15. Measuring saturable nonlinearity in atomic vapor via a direct spatial mappingJuan Wu, Pengbo Jia, Sandan Wang, Xuewen Wang, Jinpeng yuan, Lirong Wang, Yi Hu*, Zhigang Zhang, and Jingjun Xu, Optics Express, 30(24), 43012-43020 (2022)

16. Improvement of microwave electric field measurement sensitivity via dual-microwave-dressed electromagnetically induced transparency in Rydberg atoms, Jinpeng Yuan, Ting JinLirong Wang†, Liantuan Xiao, and Suotang Jia, Laser Physics Letters, 19, 125207 (2022)

17. Tailoring the pulse train of an optical frequency comb with a magnetized atomic medium, Yang Yan, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Laser Physics Letters, 19, 025201 (2022)

18. Coherent population transfer of Rydberg atoms in a dual-microwave driven five-level configurationTing Jin, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Communications, 522, 128603 (2022)

19. Tunable high-order Bessel-like beam generation based on cross-phase modulationJinpeng Yuan, Xuewen Wang, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Express, 30(10), 15978-15985 (2022)

20. Sensitivity enhancement of nonlinear refractive index measurement by Gaussian-Bessel beam assisted z-scan methodWei Gao, Sandan Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Express, 30(5), 7291-7298 (2022)

21. Enhanced microwave electric field measurement with cavity-assisted Rydberg electromagnetically induced transparency, Shaohua Li, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, Suotang Jia, Frontiers in Physics, 10, 846684- (2022)

22. Enhanced frequency up-conversion based on four-wave mixing assisted by a Bessel-Gaussian beam in 85Rb atoms, Xuewen Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics and Laser Technology, 149, 107874 (2022)

23. A dual-wavelength bandpass Faraday anomalous dispersion optical filter operating on the D1 and D2 lines of rubidium, Yang Yan, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Communications, 509, 127855 (2022)

24. Investigation of 6S1/28S1/2 two-photon transition of cesium atoms by a single 822 nm laser, Ning liu, Sandan Wang, Jinpeng Yuan+,Lirong Wang†, Liantuan Xiao, and Suotang Jia, Laser Physics Letters, 19, 025201 (2022)

25. Measurement of the quantum defects of 85Rb P and F-series via microwave-assisted electromagnetically induced transparency spectroscopy, Shaohua Li, Jinpeng Yuan+, Lirong Wang*, Liantuanxiao, and Suotang Jia, Results in Physics, 29, 104728 (2021)

26. Characterization of Rubidium thin cell properties with sandwiched structure using a multipath interferometer with an optical frequency combSandan Wang†, Jinpeng Yuan†, Lirong Wang*, Liantuanxiao, and Suotang Jia, Optics Letters, 46(17), 4284-4287 (2021)

27. Tunable optical vortex array in a two-dimensional electromagnetically induced atomic latticeJinpeng Yuan†, Hengfei Zhang†, Chaohua Wu, Lirong Wang*, Liantuanxiao, and Suotang Jia, Optics Letters, 46(17), 4184-4187 (2021)

28. All-optical tunable high-order Gaussian beam splitter based on periodic dielectric atomic structureHengfei Zhang, Jinpeng Yuan+, Chaohua Wu, Lirong Wang*, Liantuanxiao, and Suotang Jia, Optics Express, 29(16), 25439-25448 (2021)

29. High-precision three-dimensional Rydberg atom localization in a four-level atomic system, Zhang hengfei, Yuan Jin-peng*Wang Li-Rong†, Xiao Lian-Tuan, and Jia Suo-TangChinese Physics B, 30(5), 053202(2021) (suggested by Editors)

30. Coherent near-infrared light generation based on self-seeded parametric four-wave mixing in Rb vapor, Xuewen Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Laser Physics Letters, 18, 055207 (2021)

31. Coherent 420 nm laser generated by the cavity-enhanced four-wave mixing process in Rb vapor, Jinpeng Yuan, Hao Liu, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Express, 29(4), 4858-4865 (2021)

32. Efficient all-optical modulator based on a periodic dielectric atomic lattice, Jinpeng Yuan, Shichao Dong, Hengfei Zhang, Chaohua Wu, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Express, 29(2), 2712-2719 (2021)

33. Investigation on the Cs 6S1/2 to 7D electric quadrupole transition via monochromatic two-photon process at 767 nm, Sandan Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Frontiers of Physics, 16(1), 12502 (2021)

34. Sub-wavelength three-dimensional Rydberg atom localization by optical absorption microscopy, Hengfei Zhang, Jinpeng Yuan+, Chaohua Wu, Lirong Wang†, Liantuan Xiao, and Suotang Jia,Laser Physics Letters, 18, 015201 (2021)

35. Measurement of the Kerr nonlinear refractive index of the Rb vapor based on an optical frequency comb using the z-scan method, Sandan Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Express, 28(25), 38334-38342 (2020)

36. Improvement of Microwave Electric Field Measurement Sensitivity via Multi-Carrier Modulation in Rydberg Atoms, Shaohua Li, Jinpeng Yuan*, Lirong Wang*, Applied Sciences, 10, 8110 (2020)

37. Observation of an electromagnetically induced grating in cold 85Rb atoms, Hengfei Zhang, Jinpeng Yuan*, Shichao Dong, Chaohua Wu, Lirong Wang*, Applied Sciences, 10, 5740 (2020)

38. Optically tunable grating in a V + Ξ configuration involved a Rydberg state, Jinpeng Yuan, Shichao Dong, Chaohua Wu, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Optics Express, 28(16), 23820-23828 (2020)

39. Coherent 420 nm laser beam generated by four-wave mixing in Rb vapor with a single continuous wave laser, Liu Hao, Yuan Jin-peng*Wang Li-Rong†, Xiao Lian-Tuan, and Jia Suo-TangChinese Physics B, 29(4), 043203(2020)

40. Measurement of the wavefunction for a biphoton state with homodyne detection using least squares estimation, Yashuai Han, Daohua Wu, Katsuyuki Kasai, Lirong Wang†, Masayoshi Watanabe and Yun Zhang†, Journal of Optics, 22, 025202 (2020)

41. Laser frequency stabilization on 5P → 5D transition by double resonance optical pumping and two-photon transition spectroscopy in rubidium, Jinpeng Yuan, Shichao Dong, Lirong Wang†, Liantuan Xiao and Suotang Jia, Laser Physics, 30, 025201 (2020)

42. A stable frequency standard based on one-color two-photon 5S -7S transition of rubidium at 760nm , Sandan Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang JiaLaser Physics Letters, 16, 125204 (2019)

43. Controllable electromagnetically induced grating in a cascade-type atomic system, Jin-Peng Yuan, Chao-Hua Wu, Yi-Hong Li, Li-Rong Wang*, Yun Zhang†, Lian-Tuan Xiao, Suo-Tang Jia, Frontiers of Physics, 14(5), 52603 (2019) (封面文章)

44. Observation of diffraction pattern in two-dimensional optically induced atomic lattice, Jinpeng Yuan, Chaohua Wu, Lirong Wang*, Gang Chen, and Suotang Jia, Optics Letters, 44(17), 4123-4126 (2019) (highlighted as an Editor's Pick)

45. Integer and fractional electromagnetically induced Talbot effects in a ladder-type coherent atomic system, Jinpeng Yuan, Chaohua Wu, Yihong Li, Lirong Wang†, Yun Zhang, Liantuan Xiao,and Suotang Jia, Optics Express, 27(1), 92-101 (2019)

46. Rotamers of p isopropylphenol studied by hole-burning resonantly enhanced multiphoton ionization and mass analyzed threshold ionization spectroscopy, Yan Zhao, Yinghui Jin, Jiayu Hao, Yonggang Yang, Lirong Wang, Changyong Li, Suotang Jia, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 207, 328–336, (2019)

47. Experimental Study of Double Resonance Optical Pumping Spectroscopy in a Ladder-type System of 87Rb Atoms, Yihong Li, Shaohua Li, Jinpeng Yuan*, Lirong Wang **, Liantuan Xiao, and Suotang Jia,Chinese Physics Letters, 35, 093201 (2018)

48. Experimental observation of three-photon interference between a two-photon state and a weak coherent state on a beam splitter, Tingyu Li, Saburo Sakurai, Katsuyuki Kasai, Lirong Wang†, Masayoshi Watanabe, and Yun Zhang†, Optics Express, 26(16), 20442-20449 (2018)

49. Investigation on the Monochromatic Two-Photon Transition Spectroscopy of Rubidium by Using Intensity Modulation Method, Sandan Wang, Jinpeng Yuan+, Lirong Wang†, Liantuan Xiao, and Suotang Jia, Journal of the Physical Society of Japan, 87, 084301 (2018)

50. Determination of hyperfine structure constants of 5D5∕2 and 7S1∕2 states of rubidium in cascade atomic systemShaohua Li), Yihong Li, Jinpeng Yuan*, Lirong Wang **, Liantuan Xiao, and Suotang Jia, Chinese Optics Letters16(6), 060203(2018)

51. Two-color resonance enhanced multi-photon ionization and mass analyzed threshold ionization spectroscopy of 2-aminobenzonitrile and the CN substitution effectYinghui Jin Yan Zhao, Yonggang Yang, Lirong Wang, Changyong Li, Suotang JiaChemical Physics Letters692, 395–401 (2018)

52. 空间光调制器振幅和相位调制特性的实验研究,闫赛,武秀,王春云,秦宏利,元晋鹏,汪丽蓉,量子光学学报, 24(1), 127-112 (2018)

53. Experimental study of discrete diffraction behavior in a coherent atomic system, Jinpeng Yuan, Yihong Li, Shaohua Li, Changyong Li,Lirong Wang, Liantuan Xiao and Suotang JiaLaser Physics Letters, 14, 125206 (2017)

54. 纳米光纤腔中腔长诱导的相干动力学,张鸿宇,俞立先,汪丽蓉,山西大学学报, 40(4),781-788 (2017)

55. Superfluid–Mott-insulator quantum phase transition of light in a two-mode cavity array with ultrastrong coupling, Jingtao Fan, Yuanwei Zhang, Lirong Wang, Feng Mei, Gang Chen, and Suotang Jia, Physical Physics A, 95, 033842 (2017)

56. 利用铷原子双光子跃迁产生420nm蓝光的实验研究,范鹏瑞,李一鸿,李少华,元晋鹏,汪丽蓉,量子光学学报, 23(2),144-150 (2017)

57. Low intensity noise and narrow line-width diode laser light at 540nm, Lirong Wang, Ryo Tamaki, Katsuyuki Kasai, Yoshiko Okada-Shudo,Masayoshi Watanabe and Yun ZhangLaser Physics Letters, 12,  055802(2015)

58. 超低频调制光缔合光谱的实验研究, 汪丽蓉,马 杰,赵延霆,肖连团,贾锁堂,光谱学与光谱分析, 34(9), 3201-3204 (2014) ‘

59. 双模Dicke模型的一级量子相变, 俞立先,梁奇锋,汪丽蓉,朱士群,物理学报, 63(13), 13, 134204 (2014)

60. Rabi模型的光场压缩, 俞立先,梁奇锋,汪丽蓉,朱士群,物理学报, 62(16), 163011 (2013)

61. 超冷铯分子0-g长程态的振转光谱研究, 汪丽蓉,冯薪林,马杰,赵延霆,肖连团,贾锁堂,物理学报, 62(18), 183301 (2013)

62. The laser-intensity dependence of the photoassociation spectrum of the ultracold Cs2(6S1/2+6P1/2) 0+u long-range molecular state, Jin Li, Feng Guo-Sheng, Wu Ji-Zhou, Ma Jie, Wang Li-Rong†, Xiao Lian-Tuan, and Jia Suo-TangChinese Physics B, 22, 088701(2013)

63. Experimental measurement of the absolute frequencies and hyperfine coupling constants of 133Cs using a femtosecond optical frequency comb, JIN Li, ZHANG Yi-Chi, XIANG Shao-Shan, WANG Li-Rong, MA Jie, ZHAO Yan-Ting, XIAO Lian-Tuan, JIA Suo-Tang, Chinese Physics Letters, 30, 103201(2013)

64. Experimental observation of the lowest levels in the photoassociation spectroscopy of the 0-g purely-long-range state of Cs2, Yichi Zhang, Jie Ma,* Jizhou Wu, Lirong Wang, Liantuan Xiao, and Suotang Jia, Physics Review A, 87, 030503(R) (2013)

65. Direct measurement of laser-induced frequency shift rate of ultracold cesium molecules by analyzing losses of trapped atoms, Yichi Zhang, Jie Ma, Yuqing Li, Jizhou Wu, Linjie Zhang, Gang Chen, Lirong Wang,Yanting Zhao, Liantuan Xiao, and Suotang JiaApplied Physics Letters, 101, 131114 (2012)

66. 飞行时间质谱探测磁光阱中超冷分子离子的实验研究,元晋鹏,姬中华,杨艳,张洪山,赵延霆,马杰,汪丽蓉,肖连团,贾锁堂,物理学报, 61(18), 183301 (2012)

67. Precise measurement of the line width of the photoassociation spectra of ultracold molecules by using a frequency shifter, Wu Ji-Zhou, Ma Jie†, Ji Zhong-Hua, Zhang Yi-Chi,Li Yu-Qing, Wang Li-Rong, Zhao Yan-Ting, Xiao Lian-Tuan, and Jia Suo-TangChinese Physics B, 21(9), 093701 (2012)

68. High sensitive detection of high-order partial wave scattering in photoassociation of ultralcold atoms, Li Yu-Qing, Ma Jie, Wu Ji-Zhou, Zhang Yi-Chi, Zhao Yan-Ting, Wang Li-Rong), Xiao Lian-Tuan), and Jia Suo-Tang, Chinese Physics B, 21(4), 043404 (2012)

69. Improvement of signal-to-noise ratio of the Cs2 photoassociation spectroscopy by using dark SPOT magneto-optical trap, Yichi Zhang, Jizhou Wu, Yuqing Li, Jie Ma, Lirong Wang, Yanting Zhao, Liantuan Xiao, Suotang Jia, Journal of Molecular Spectroscopy, 273, 11–15 (2012)

70. High Sensitivity Measurement and Accurate Analysis of the Vibrational Spectroscopy Near the6S1/2 +6P3/2Dissociation limit for 1g State of Cs2, Yuqing LI, Jie MA, Jizhou WU, Yichi ZHANG, Gang CHEN, Yanting ZHAO, Lirong WANG, Liantuan XIAO, and Suotang JIA Journal of the Physical Society of Japan, 81, 044301 (2012)

71. 简并微扰法求解拉比模型, 裴笑珍,汪丽蓉,贾锁堂,量子光学学报, 18(4), 322 (2012)

72. A direct frequency comb for two-photon transition spectroscopy in a cesium vapor, Zhang Yi-Chi, Wu Ji-Zhou, Li Yu-Qing, Jin Li, Ma Jie†,Wang Li-Rong, Zhao Yan-Ting, Xiao Lian-Tuan, and Jia Suo-TangChinese Physics B, 21(11), 113701 (2012)

73. Investigation of ultracold atoms and molecules in a dark magneto-optical trap, Wang Li-Rong†, Ji Zhong-Hua, Yuan Jin-Peng, Yang Yan, Zhao Yan-Ting, Ma Jie, Xiao Lian-Tuan, and Jia Suo-TangChinese Physics B, 21(11), 113402 (2012)

74. 超冷铷铯极性分子振转光谱的实验研究, 杨艳,姬中华,元晋鹏,汪丽蓉,赵延霆,马杰,肖连团,贾锁堂,物理学报, 61(21), 213301(2012)

75. Photoassociative formation of ultracold RbCs molecules in the (2) 3Π state, Zhonghua Ji, Hongshan Zhang, Jizhou Wu, Jinpeng Yuan, Yonggang Yang, Yanting Zhao, Jie Ma, Lirong Wang, Liantuan Xiao, and Suotang JiaPhysical Review A, 85, 013401 (2012)

76. Photoassociative Production and Detection of Ultracold Polar RbCs Molecules, JI Zhong-Hua, ZHANG Hong-Shan, WU Ji-Zhou, YUAN Jin-Peng, ZHAO Yan-Ting**, MA Jie, WANG Li-Rong, XIAO Lian-Tuan, JIA Suo-TangChinese Physics Letters, 28(8), 083701 (2011)

77. High sensitive determination of laser-induced frequency shifts of ultracold cesium molecules, Jizhou Wu, Zhonghua Ji, Yichi Zhang, Lirong Wang, Yanting Zhao, Jie Ma,* Liantuan Xiao, and Suotang Jia, Optics Letters, 36(11), 201(2011)

78. Dependence of loading time on control parameters in a standard vapour loaded magneto optical trap, Zhang Yi-Chi, Wu Ji-Zhou, Li Yu-Qing, Ma Jie,Wang Li-Rong, Zhao Yan-Ting), Xiao Lian-Tuan, and Jia Suo-Tang, Chinese Physics B, 20(12), 123701 (2011)

79. Cold cesium molecules produced directly in a magneto optical trap, Zhang Hong-Sha, Ji Zhong-Hua, Yuan Jin-Peng, Zhao Yan-Ting, Ma Jie Wang Li-Rong, Xiao Lian-Tuan, and Jia Suo-Tang, Chinese Physics B, 20(12), 123702 (2011)

80. High sensitive trap loss spectroscopic detection of the lowest vibrational levels of ultracold molecules, Jizhou Wu, Jie Ma,* Yichi Zhang, Yuqing Li, Lirong Wang, Yanting Zhao, Gang Chen, Liantuan Xiao* and Suotang Jia, Physical Chemistry Chemical Physics, 13, 18921-18925, (2011)

81. Investigation of cold collision in a Rb–Cs magneto-optical trap, Zhong-Hua Ji, Ji-Zhou Wu, Hong-Shan Zhang, Teng-Fei Meng, Jie Ma, Li-Rong Wang, Yan-Ting Zhao1, Lian-Tuan Xiao and Suo-Tang Jia, Journal of physics B-atomic molecular and optical physics, 44, 025202 (2011)

82. Ionization Detection of Ultracold Ground State Cesium Molecules, JI Zhong-Hua, WU Ji-Zhou MA Jie, FENG Zhi-Gang, ZHANG Lin-Jie, ZHAO Yan-Ting, WANG Li-Rong**, XIAO Lian-Tuan, JIA Suo-Tang, Chinese Physics Letters, 27(5), 053701 (2010)

83. Direct Measurement of the Cs2 0 u(P3/2) High-Lying Vibrational Spectroscopy Using Photon Counting, Jie MA, Lirong WANG, Yanting ZHAO, Liantuan XIAO, and Suotang JIA, Journal of the Physical Society of Japan, 78(6), 064302 (2009)

84. High sensitive photoassociation spectroscopy of the Cs molecular 0 u and 1g long-range states below the 6S1/2+6P3/2 limit, Jie Ma *, Lirong Wang, Yanting Zhao, Liantuan Xiao *, Suotang Jia, Journal of Molecular Spectroscopy, 255, 106–110 (2009)

85. Optimum conditions for producing Cs2 molecular condensates by stimulated Raman adiabatic passage, ZhiFang Feng, WeiDong Li, LiRong Wang, LianTuan Xiao†, and SuoTang Jia Physical review A,80, 043620 (2009)

86. 利用锁相放大器技术探测铯冷原子荧光谱的实验研究, 冀炜帮,王贵平,马杰,汪丽蓉,肖连团,贾锁堂,光子学报, 37(5), 969-972 (2008)

87. Arbitrarily copropagating superluminal and slow light by controllable one-photon detuning in trapped cold atoms, Yanting Zhao, Jie Ma, Xianli Zhang, Lirong Wang, Liantuan Xiao, 1, and Suotang Jia, Optics Express, 16(7), 474-475 (2008)

88. Nonlinear coherent spectroscopy in a degenerate two-level atomic ensemble for a transition Fg0 →Fe1, Li-Rong Wang, Jie Ma, Jian-Ming Zhao, Lian-Tuan Xiao, Suo-Tang Jia, Optik, 119, 185–191 (2008)

89. Research on ultracold cesium molecule long-range states by high-resolution photoassociative spectroscopy, WANG LiRong, MA Jie, JI WeiBang, WANG GuiPing, XIAO LianTuan† & JIA SuoTang, Science in China Series G: Physics, Mechanics & Astronomy, 51, 147-156 (2008)

90. 磁光阱中铯冷原子碰撞损耗率系数的测量, 王贵平,冀炜帮,马杰,汪丽蓉,肖连团,贾锁堂, 中国激光, 35(2), 221-224 (2008)

91. Ultra-high resolution trap-loss spectroscopy of ultracold 133Cs atoms long-range states in magneto-optical trap, L. R. Wang, J. Ma, W. B. Ji, G. P. Wang, L. T. Xiao*, and S. T. Jia, Laser Physics, 17(9), 1171-1175 (2007)

92. Saturation of Photassociation in Cs Magneto-optical Trap, Ma Jie, Wang Lirong, Ji Weibang, Xiao Liantuan and Jia Suotang, Chinese Physics Letters, 24(7), 1904-1907(2007)

93. 光缔合制备超冷分子及其光谱特性研究, 贾锁堂,汪丽蓉,马杰,肖连团,山西大学学报(自然科学版), 30(2), 181-187(2007)

94. 基于振幅调制的超冷铯原子高分辨光缔合光谱的实验研究, 汪丽蓉,马杰,张临杰,肖连团,贾锁堂,物理学报, 56(11), 6373-6377(2007)

95. 利用高分辨率光缔合光谱学研究超冷铯分子的长程态,汪丽蓉,马杰,冀炜帮,王贵平,肖连团,贾锁堂,中国科学G辑:物理学 力学 天文学37(6), 767-776 (2007)

96. High sensitive photoassociation spectroscopy based on modulated ultra-cold Cs atoms, Lirong Wang, Jie Ma, Changyong Li, Jianmiang Zhao, Liantuan Xiao and Suotang Jia,Applied Physics B, 98(10), 53-57(2007)

97. Absolute frequency stabilization of a diode laser to cesium atom-molecular hyperfine transitions via modulating molecules, Jie Ma, Lirong Wang, Yanting Zhao, Liantuan Xiao, and Suotang Jia, Applied Physics Letters, 91, 161101(2007)

98. 光缔合产生超冷分子及其光谱测量, 汪丽蓉,贾锁堂,量子光学学报, 12(3), 143-150 (2006)

99. Tunable and frequency-stabilized diode laser using temperature-dependent energy fluorescence, Liantuan Xiao,a Tao Huang, Lirong Wang, Jianming Zhao, and Suotang Jia Applied Physics Letters, 88, 231104(2006)

100. Observation of Four-wave Mixing In Cesium Atoms Using a Noncycling Transition, Wang Lirong, Zhao Yanting, Ma Jie, Zhao Jianming, Xiao Liantuan, and Jia Suotang, Chinese Physics, 15(6), 1268-1272 (2006)

101. Laser offset-frequency locking against energy pooling fluorescence in thermal caesium vapour, Liantuan Xiao, Tao Huang, Lirong Wang, Jianming Zhao and Suotang JiaMeasurement Science and Technology, 17, L5-L8 (2006)

102. Experimental investigation of slow light propagation in degenerate two-level system, Wang Lirong, Zhao Yanting, Ma Jie, Zhao Jianming, Xiao Liantuan, Jia Suotang, Chinese Physics, 15(2), 365-370 (2006)

103. Absorption resonances in type three-level system in cesium vapor cell with buffer gas, Wang Lirong, Ma Jie, Zhao Jianming, Xiao Liantuan, Jia Suotang, Chinese Optics Letters, 4(1), 55-58 (2006)

104. 磁场对简并二能级系统相干特性的影响, 赵建明,汪丽蓉,赵延霆,马杰,肖连团,贾锁堂,物理学报, 54(12), 5093-5096 (2005)

105. High-Sensitivity Detection of Methane Near 6106 cm-1 Using Tunable External-Cavity Diode Laser, Weiguang MA, Wangbao YIN, Lei DONG, Lirong WANG, Changyong LI and Suotang JIA, Japanese Journal of Applied Physics, 44(4), 1961–19652005

106. Research on the distributed optical remote sensing of methane employing single laser source,Chinese Optics Letters, 21(1),76-78 (2004)

107. Research on the distributed optical remote sensing of methane employing single laser source, Wangbao Yin, Weiguang Ma, Lirong Wang, Jianming Zhao, Liantuan Xiao, Suotang Jia, Chinese Optics Letters, 2(2), 86-88(2004)

108. 靶材料BRDF现场模拟测量,尹王保,汪丽蓉,赵延霆,李昌勇,肖连团,贾锁堂,光子学报32(4), 473-476 (2003)

109. Experimental measurement of absorption and dispersion in V-type cesium atom, Jianming Zhao*, Lirong Wang, Liantuan Xiao, Yanting Zhao, Wangbao Yin, Suotang JiaOptics communication, 206, 341-345 (2002)

110. Experimental investigation of non-linear selective reflection at the interface of Cs atomic vapor and quartz, Jianming Zhao, Yanting Zhao, Lirong Wang, Liantuan Xiao, Suotang Jia, Applied Physics B, 75, 553-555(2002)

111. Electromagnetically-induced transparency in a multi-V-type system in cesium atomic vapor, Jianming Zhao*, Wangbao Yin, Lirong Wang, Liantuan Xiao, Suotang Jia, Chinese Physics, 11(3), 241-244 (2002)

112. Thermal-energy pooling collisions in Cesium Vapor 6P3/2+6P3/2→7PJ+6S1/2, Wang Lirong, Zhao Jianming, Xiao Liantuan, and Jia Suotang, Chinese Journal of Laser, 11(6), 421-424 (2002)

113. Cs原子6P-7P态能量积聚效应的温度特性研究,赵建明,肖连团,汪丽蓉,贾锁堂,物理学报, 51(11), 2485-24888 (2002)