Jian-Wei Pan

Category
Position
Email
pan@ustc.tsg211.com
Address
No.99 Xiupu Road, Pudong District, Shanghai, China
Introduction

Prof. Jian-Wei Pan, born in Mar, 1970, is a full professor of physics at the University of Science and Technology of China. He obtained his Ph.D. degree in 1999 from the University of Vienna. In 2011, he was elected as the academician of Chinese Academy of Sciences (CAS). In 2011, he was appointed as the chief scientist of the quantum science experiments satellite. In 2012, he was elected as TWAS Fellow. In 2014, he was appointed as the director of the CAS Center for Excellence in Quantum Information and Quantum Physics.

The research of Prof. Jian-Wei Pan focuses on quantum information and quantum foundations. As one of pioneers in experimental quantum information science, he has accomplished a series of profound achievements, which has brought him worldwide fame. Due to his numerous progresses on quantum communication and multi-photon entanglement manipulation, quantum information science has become one of the most rapidly developing fields of physical science in China in recent years. His work in the field of quantum information and quantum communication has been recognized by Nature as “features of the year 2012” and “the science events that shaped the year 2016 and 2017”, by Science as “Breakthrough of the Year 1998”, by the American Physical Society websites as “The top physics stories of the year” (six times), and by the Physics World, Institute of Physics as “Highlights of the year” (six times). Within China, his work has been selected for eleven times as “The Top Ten Annual Scientific and Technological Progresses in China”.

Related Publications

  • Zhu, Q., Sun, Z., Gong, M., Chen, F., Zhang, Y., Wu, Y., Ye, Y., Zha, C., Li, S., Guo, S., Qian, H., Huang, H., Yu, J., Deng, H., Rong, H., Lin, J., Xu, Y., Sun, L., Guo, C., Li, N., Liang, F. -T., Peng, C. -Z., Fan, H., Zhu, X. & Pan, J. -W. Observation of Thermalization and Information Scrambling in a Superconducting Quantum Processor. Physical Review Letters 128, 1-6 (2022).
  • Zhu, Q., Cao, S., Chen, F., Chen, M. -C., Chen, X., Chung, T., Deng, H., Du, Y., Fan, D., Gong, M., Guo, C., Guo, C., Guo, S., Han, L., Hong, L., Huang, H., Huo, Y., Li, L., Li, N., Li, S., Li, Y., Liang, F. -T., Lin, C., Lin, J., Qian, H., Qiao, D., Rong, H., Su, H., Sun, L., Wang, L., Wang, S., Wu, D., Wu, Y., Xu, Y., Yan, K., Yang, W., Yang, Y., Ye, Y., Yin, J., Ying, C., Yu, J., Zha, C., Zhang, C., Zhang, H., Zhang, K., Zhang, Y., Zhao, H., Zhao, Y., Zhou, L., Lu, C. -Y., Peng, C. -Z., Zhu, X. & Pan, J. -W. Quantum computational advantage via 60-qubit 24-cycle random circuit sampling. Science Bulletin 67, 240-245 (2022).
  • Zhao, B. & Pan, J. -W. Quantum control of reactions and collisions at ultralow temperatures. Chemical Society reviews 51, 1685-1701 (2022).
  • You, X., Zheng, M., Chen, S., Liu, R., Qin, J., Xu, M., Ge, Z., Chung, T., Qiao, Y., Jiang, Y., Zhong, H., Chen, M. -C., Wang, H., He, Y. -M., Xie, X., Li, H., You, L., Schneider, C., Yin, J., Chen, T. -Y., Benyoucef, M., Huo, Y. -H., Sven, ofling, Zhang, Q., Lu, C. -Y. & Pan, J. -W. Quantum interference with independent single-photon sources over 300 km fiber. Advanced Photonics 4, 1-7 (2022).
  • Zhao, Y., Ye, Y., Huang, H., Zhang, Y., Wu, D., Guan, H., Zhu, Q., Wei, Z., He, T., Cao, S., Chen, F., Chung, T., Deng, H., Fan, D., Gong, M., Guo, C., Guo, S., Han, L., Li, N., Li, S., Li, Y., Liang, F. -T., Lin, J., Qian, H., Rong, H., Su, H., Sun, L., Wang, S., Wu, Y., Xu, Y., Ying, C., Yu, J., Zha, C., Zhang, K., Huo, Y. -H., Lu, C. -Y., Peng, C. -Z., Zhu, X. & Pan, J. -W. Realization of an Error-Correcting Surface Code with Superconducting Qubits. Physical Review Letters 129, (2022).
  • Li, S., Fan, D., Gong, M., Ye, Y., Chen, X., Wu, Y., Guan, H., Deng, H., Rong, H., Huang, H., Zha, C., Yan, K., Guo, S., Qian, H., Zhang, H., Chen, F., Zhu, Q., Zhao, Y., Wang, S., Ying, C., Cao, S., Yu, J., Liang, F. -T., Xu, Y., Lin, J., Guo, C., Sun, L., Li, N., Han, L., Peng, C. -Z., Zhu, X. & Pan, J. -W. Realization of Fast All-Microwave Controlled-Z Gates with a Tunable Coupler. Chinese Physics Letters 39, (2022).
  • Su, Z., Yang, H., Cao, J., Wang, X., Rui, J., Zhao, B. & Pan, J. -W. Resonant Control of Elastic Collisions between Na 23 K 40 Molecules and K 40 Atoms. Physical Review Letters 129, 33401 (2022).
  • Zheng, Y. -G., Zhu, Z. -H., Liu, Y., Zhang, W. -Y., Wang, H. -Y., Yu, S. -T., Luo, A., Sun, H., Yuan, Z. -S. & Pan, J. -W. Robust site-resolved addressing via dynamically tracking the phase of optical lattices. Optics Letters 47, 4239 (2022).
  • Li, Y., Liao, S. -K., Cao, Y., Ren, J. -G., Liu, W. -Y., Yin, J., Shen, Q., Qiang, J., Zhang, L., Yong, H. -L., Lin, J., Li, F. -Z., Xi, T., Li, L., Shu, R., Zhang, Q., Chen, Y. -A., Lu, C. -yang, Liu, N. -L., Bin Wang, X. -, Wang, J. -Y., Peng, C. -Z. & Pan, J. -wei. Space–ground QKD network based on a compact payload and medium-inclination orbit. Optica 9, 933 (2022).
  • Liu, X. -P., Yao, X. -C., Li, X., Wang, Y., Huang, C., Deng, Y. J., Chen, Y. -A. & Pan, J. -W. Temperature-Dependent Decay of Quasi-Two-Dimensional Vortices across the BCS-BEC Crossover. Physical Review Letters 129, 163602 (2022).