Jun Zhang

Category
Position
Email
zhangjun@happyjiayi.com
Address
Room B1009-2, Physical Science Park, University of Science & Technology of China, 96 Jin Zhai Rd., Hefei
Introduction

Dr. Jun Zhang is a full professor at Hefei National Laboratory of Physical Sciences at Microscale, University of Science and Technology of China (USTC). Dr. Zhang received his bachelor’s degree and PhD both from USTC at 2002, and 2007, respectively. From August 2007 to January 2011, he had been working in University of Geneva as a postdoctoral researcher. At January 2011 he came back to USTC. Dr. Zhang was promoted as a full professor starting from July 2016. Currently his research interests include quantum communication, single-photon detection and applications, quantum random number generator and quantum Lidar. For high-speed single-photon detection, he achieved a world record in terms of working frequency, which thoroughly resolved the long-standing bottleneck problem of working frequency for single-photon detectors. Then he implemented board-integrated and monolithically-integrated InGaAs/InP single-photon detectors with a gating frequency of 1.25 GHz for the first time, which have been deployed in large-scale for the giant project of “Beijing-Shanghai Quantum Communication Backbone Network”. Also, he experimentally demonstrated a quantum random number generator (QRNG) with a bit rate of 68 Gbps, which had been reported by a well-known American scientific magazine, MIT Technology Review, entitled as “World's Fastest Quantum Random Number Generator Unveiled in China”. So far, Dr. Zhang has published around 50 papers in well-known journals including Nature (1), Nature Photonics (3), Physical Review Letters (8), Physics Reports (1), Light: Science & Applications (1), Optica (2), Optics Letters (2), and Optics Express (4), with over 2300 citations (Google Scholar) and h-index of 22, and has 14 authorized/accepted invent patents as well.

Related Publications

  • Zhao, S. -R., Zhang, Y. -zhe, Liu, W. -Z., Guan, J. -Y., Zhang, W., Li, C. -long, Bai, B., Li, M. -H., Liu, Y., You, L., Zhang, J., Fan, J., Xu, F., Zhang, Q. & Pan, J. -W. Field Demonstration of Distributed Quantum Sensing without Post-Selection. Physical Review X 11, 31009 (2021).
  • Bai, B., Huang, J., Qiao, G. -R., Nie, Y. -Q., Tang, W., Chu, T., Zhang, J. & Pan, J. -W. 18.8 Gbps real-time quantum random number generator with a photonic integrated chip. Applied Physics Letters 118, 264001 (2021).
  • Liu, W. -Z., Li, M. -H., Ragy, S., Zhao, S. -R., Bai, B., Liu, Y., Brown, P. J., Zhang, J., Colbeck, R., Fan, J., Zhang, Q. & Pan, J. -W. Device-independent randomness expansion against quantum side information. Nature Physics 17, (2021).
  • Yu, Y., Sun, P. -F., Zhang, Y. -zhe, Bai, B., Fang, Y. -Q., Luo, X. -Y., An, Z. -Y., Li, J., Zhang, J., Xu, F., Bao, X. -H. & Pan, J. -W. Measurement-Device-Independent Verification of a Quantum Memory. Physical Review Letters 127, 160502 (2021).
  • Wu, C., Liu, J., Huang, X., Li, Z. -P., Yu, C., Ye, J. -T., Zhang, J., Zhang, Q., Dou, X., Goyal, V. K., Xu, F. & Pan, J. -W. Non–line-of-sight imaging over 1.43 km. Proceedings of the National Academy of Sciences of the United States of America 1-7 (2021).
  • Li, Z. -P., Ye, J. -T., Huang, X., Jiang, P. -Y., Cao, Y., Hong, Y., Yu, C., Zhang, J., Zhang, Q., Peng, C. -Z., Xu, F. & Pan, J. -W. Single-photon imaging over 200 km. Optica 8, 344 (2021).
  • Chen, Y. -A., Zhang, Q., Chen, T. -Y., Cai, W. -Q., Liao, S. -K., Zhang, J., Chen, K., Yin, J., Ren, J. -G., Chen, Z., Han, S. -L., Yu, Q., Liang, K., Zhou, F., Yuan, X., Zhao, M. -S., Wang, T. -Y., Jiang, X., Zhang, L., Liu, W. -Y., Li, Y., Shen, Q., Cao, Y., Lu, C. -Y., Shu, R., Wang, J. -Y., Li, L., Le Liu, N., Xu, F., Bin Wang, X. -, Peng, C. -Z. & Pan, J. -W. An integrated space-to-ground quantum communication network over 4,600 kilometres. Nature 589, 214-219 (2021).
  • Wang, B. -X., Mao, Y. -Q., Shen, L., Lei, Z., Lan, X. -B., Ge, D., Gao, Y., Li, J., Tang, Y. -L., Tang, S. -B., Zhang, J., Chen, T. -Y. & Pan, J. -W. Long-distance transmission of quantum key distribution coexisting with classical optical communication over weakly-coupled few-modefiber. Optics Express 28, (2020).
  • Fang, Y. -Q., Chen, W., Ao, T. -H., Liu, C., Wang, L., Gao, X. -J., Zhang, J. & Pan, J. -W. InGaAs/InP single-photon detectors with 60\% detection efficiency at 1550 nm. Review of Scientific Instruments 91, (2020).
  • Da Li, Z. -, Yin, X. -fei, Wang, Z., Liu, L. -zheng, Zhang, R., Zhang, Y. -zhe, Jiang, X., Zhang, J., Li, L., Liu, N. L., Zhu, X., Xu, F., Chen, Y. -A. & Pan, J. -W. Photonic realization of quantum resetting. Optica 7, (2020).
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