• Principal Investigator, Assistant Professor, Doctoral Advisor
• College of Future Technology
  National Biomedical Imaging Center

• 个人简介

  Dr. Hanqing Xiong’s research is focused on nonlinear molecular spectroscopy and its application in chemical and biomedical imaging. He is now an assistant professor at the College of Future Technology, Peking University. In recent years, he has published systematic research innovations in the fields of (i) mesoscale connectomics and (ii) vibrational spectroscopy & imaging. People interested in these two topics can find the details in my Representative Publications below.

• 所授课程

  Fundamentals of Nonlinear Optics (Elective, 3 credits)
  Fundamentals of molecular spectroscopy (Elective, 3 credits)

• 个人履历

  2021. 03 – now Assistant Professor, National Biomedical Imaging Center, College of Future Technology, Peking University, Beijing, China
  2020. 06 – 2021. 03 Postdoc, Chemistry, Columbia University, New York, US
  Ph. D. 2020 Chemistry, Columbia University
  M.S. 2015 Biomedical Engineering, Huazhong University of Science and Technology
  BE 2012 Biomedical Engineering, Huazhong University of Science and Technology

• 承担项目

  Research on hyperspectral Stimulated Raman fluorescence Imaging without background, National Natural Science Foundation of China, January 2023 -- December 2026, 530,000 yuan, PI
  Ministry of Science and Technology, PRC, Science and Technology Innovation 2030 -- "Brain Science and brain-like Research", 2021ZD0202504, The Dynamic regulation of acquired factors on the formation of synapses and neural circuits, 2021-2026-12, RMB 2.189 million, ParticipationResearch on hyperspectral Stimulated Raman fluorescence Imaging without background, National Natural Science Foundation of China, January 2023 -- December 2026, 530,000 yuan, PI
  Ministry of Science and Technology, PRC, Science and Technology Innovation 2030 -- "Brain Science and brain-like Research", 2021ZD0202504, The Dynamic regulation of acquired factors on the formation of synapses and neural circuits, 2021-2026-12, RMB 2.189 million, ParticipationResearch on hyperspectral Stimulated Raman fluorescence Imaging without background, National Natural Science Foundation of China, January 2023 -- December 2026, 530,000 yuan, PI
  Ministry of Science and Technology, PRC, Science and Technology Innovation 2030 -- "Brain Science and brain-like Research", 2021ZD0202504, The Dynamic regulation of acquired factors on the formation of synapses and neural circuits, 2021-2026-12, RMB 2.189 million, Participation

• 代表性论文及论著

  Vibrational spectroscopy & imaging:
  1. Xiong, H. +, Qian, N. +, Miao, Y., Zhao, Z., Chen, C., & Min, W., 2021. Super-resolution vibrational microscopy by stimulated Raman excited fluorescence. Light: Science & Applications, 10(1), 1-10. (+Co-first author)
  2. Xiong, H., & Min, W., 2020. Combining the best of two worlds: Stimulated Raman excited fluorescence. The Journal of Chemical Physics, 153(21), 210901.
  3. Xiong, H., Qian, N., Zhao, Z., Shi, L., Min, W., 2020. Background-free imaging of chemical bonds by a simple and robust frequency-modulated stimulated Raman scattering microscopy. Optics Express, 28, 15663-15677.
  4. Xiong, H., Lee, J., Zare, R. N., Min, W., 2020. Strong Electric Field Observed at the Interface of Aqueous Microdroplets. The journal of physical chemistry letters, 11 (17), 7423–7428.
  5. Xiong, H.+, Shi, L.+, Wei, L., Shen, Y., Long, R., Zhao, Z. and Min, W., 2019. Stimulated Raman excited fluorescence spectroscopy and imaging. Nature Photonics, 13 (6), 412-417. (+Co-first author)
  Mesoscale connectomics:
  6. Wang, X.+, Xiong, H.+, Liu, Y.+, Yang, T.+, Li, A., Huang, F., Yin, F., Su, L., Liu, L., Li, N. and Li, L., 2021. Chemical sectioning fluorescence tomography: high-throughput, high-contrast, multicolor, whole-brain imaging at subcellular resolution. Cell Reports, 34(5), p.108709. (+Co-first author)
  7. Xiong, H., Zhou, Z., Zhu, M., Lv, X., Li, A., Li, S., Li, L., Yang, T., Wang, S., Yang, Z., Xu, T., Luo, Q., Gong, H. and Zeng, S., 2014. Chemical reactivation of quenched fluorescent protein molecules enables resin-embedded fluorescence microimaging. Nature communications, 5, p.3992.