Faculty
Sheng-Jun Yang, Associate Researcher at the SUSTech Institute for Quantum Science and Engineering. Yang’s research interest is experimental atomic physics and quantum optics, special focus is on quantum memory, precision measurement of gravity and weak magnetism. Yang has published 13 peer-reviewed journal articles including Nat. Photonics (3), PRLs (6), and has received about 500 citations based on Google Scholar.
Research Interest
quantum optics; Precision Measurement; atom interferometry; atom magnetometer; cold atoms
Education Background
2008.9–2015.7 PhD., Department of Modern Physics, University of Science and Technology of China
2004.9–2008.7 Bachelor, Department of Modern Physics, University of Science and Technology of China
Working Experience
2018.12–now Research associate, Shenzhen Institute for Quantum Science and Engineering, Southern University of Science and Technology
2015.9–2018.10 Post-doctor, Department of Modern Physics, University of Science and Technology of China
Papers
[1] Yuan, L., Wu, J., Yang, S.-J. (2023). Current Status and Prospects on High-Precision Quantum Tests of the Weak Equivalence Principle with Cold Atom Interferometry. Symmetry, 15, 1769.
[2] Duan, Z.-X., Wu, W.-T., Lin. Y.-T., Yang, S.-J. (2022). Simple and active magnetic-field stabilization for cold atom experiments. Review of Scientific Instruments, 93, 123201.
[3] Li, Z.-D., Mao, Y.-L., M. Weilenmann, A. Tavakoli, Chen H., Feng L.-X., Yang, S.-J., M.-O. Renou, D. Trillo, T. P. Le, N. Gisin, A. Acn, M. Navascus, Z. Wang, J. Fan (2022). Testing real quantum theory in an optical quantum network. Physical Review Letters, 128, 040402.
[4] Wang, X.-J., Yang, S.-J., Sun, P.-F., Jin, B., Li, J., Zhou, M.-T., Bao, X.-H., Pan, J.-W. (2021). Cavity-enhanced atom-photon entanglement with subsecond lifetime. Physical Review Letters, 126(9), 090501.
[5] Jing, B., Wang, X.-J., Yu, Y., Sun, P.-F., Jiang, Y., Yang, S.-J., Jiang, W.-H., Luo, X.-Y., Zhang, J., Jiang, X., Bao, X.-H., Pan, J.-W. (2019). Entanglement of three quantum memories via interference of three single photons. Nature Photonics, 13(13), 210 - 213.
[6] Long, J.-B., Yang, S.-J., Chen, S., & Pan, J.-W. (2018). Magnetic-enhanced modulation transfer spectroscopy and laser locking for 87Rb repump transition. Optics Express, 26(21), 27773–27786.
[7] Yang, S.-J., Rui, J., Dai, H.-N., Jin X.-M., Chen, S., & Pan, J.-W. (2018). High-contrast transparency comb of the electromagnetically-induced-transparency memory. Physical Review A, 98(3), 033802.
[8] Li, J., Zhou, M.-T., Jing, B., Wang, X.-J., Yang, S.-J., Jiang, X., Mølmer, Klaus, Bao, X.-H., & Pan, J.-W. (2016). Hong-Ou-Mandel interference between two deterministic collective excitations in an atomic ensemble. Physical Review Letters, 117(18), 180501.
[9] Yang, S.-J., Wang, X.-J., Bao, X.-H., & Pan, J.-W. (2016). An efficient quantum light–matter interface with sub-second lifetime. Nature Photonics, 10(6), 381–384.
[10] Rui, J., Jiang, Y., Yang, S.-J., Zhao, B., Bao, X.-H., & Pan, J.-W. (2015). Operating spin echo in the quantum regime for an atomic-ensemble quantum memory. Physical Review Letters, 115(13), 133002.
[11] Yang, S.-J., Wang, X.-J., Li, J., Rui, J., Bao, X.-H., & Pan, J.-W. (2015). Highly retrievable spin-wave–photon entanglement source. Physical Review Letters, 114(21), 210501.
[12] Yang, S.-J., Bao, X.-H., & Pan, J.-W. (2015). Modulation of single-photon-level wave packets with two-component electromagnetically induced transparency. Physical Review A, 91(5), 53805.
[13] Dai, H.-N., Zhang, H., Yang, S.-J., Zhao, T.-M., Rui, J., Deng, Y.-J.,Li, L., Liu, N.-L., Chen, S., Bao, X.-H., Jin, X.-M., Zhao, B., & Pan, J.-W. (2012). Holographic storage of biphoton entanglement. Phys. Rev. Lett. 108(21), 210501.
[14] Zhang, H., Jin, X.-M., Yang, J., Dai, H.-N., Yang, S.-J., Zhao, T.-M., Rui, J., He, Y., Jiang, X., Yang, F., Pan, G.-S., Yuan, Z.-S., Deng, Y.-J., Chen, Z.-B., Bao, X.-H., Chen, S., Zhao, B., & Pan, J.-W. (2011). Preparation and storage of frequency-uncorrelated entangled photons from cavity-enhanced spontaneous parametric down conversion. Nature Photonics, 5(10), 628–632.
Patents
[1] 一种适用于冷原子实验的前级原子预冷却系统,陈斌、袁亮、杨胜军、范靖云,中国发明专利,申请(专利) 号:2022105182552,申请日:2022-05-13,实质审查阶段。
[2] 单束光折返泵浦探测构型的磁场测量方法以及原子磁力仪,张卫东、徐晓天、杨胜军、范靖云,中国发明专利,申请(专利) 号:2021112259888,申请日:2021-10-21,已授权。
[3] 一种磁场梯度测量方法以及原子磁力梯度仪系统,徐晓天、杨胜军、范靖云,中国发明专利,申请(专利) 号:2021108428760,申请日:2021-07-23,实质审查阶段。
[4] 一种磁场测量方法及原子磁力仪系统,徐晓天、杨胜军、陈斌、范靖云,中国发明专利,申请(专利) 号:2021105388314,申请日:2021-05-18,实质审查阶段。
[5] 适用于原子干涉重力仪的振动噪声修正补偿方法,陈斌、杨胜军、陈帅、潘建伟,中国发明专利,申请(专利) 号:2018114136842,申请日:2018-11-20,已授权。
[6] 一种三维主动减振控制方法及系统,陈斌、杨胜军、陈帅、潘建伟,中国发明专利,申请(专利) 号:2018111963148,申请日:2018-10-15,实质审查阶段。
[7] 一种用于原子干涉仪探头的磁场系统,杨胜军、谢宏泰、陈帅、潘建伟,中国发明专利,申请(专利) 号:2018101354552,申请日:2018-02-09,实质审查阶段。
[8] 一种原子布局数探测系统,谢宏泰、杨胜军、陈帅、潘建伟,中国发明专利,申请(专利) 号:2018100765035,申请日:2018-01-25,实质审查阶段。
[9] 一种适用于小型化原子干涉仪的真空结构,陈帅、龙金宝、谢宏泰、杨胜军、潘建伟,中国发明专利,申请(专利) 号:2017114391860,申请日:2017-12-25,已授权。
[10] 一种适用于冷原子干涉精密测量的双激光器系统,龙金宝、杨胜军、陈帅、潘建伟,中国发明专利,申请(专利) 号:2017114391447,申请日:2017-12-25,已授权。