Category
Position
Email
tychen@ustc.edu.cn
Address
Room B1013-2, Physical Science Park, University of Science & Technology of China, 96 Jin Zhai Rd., Hefei
Introduction
Dr. Teng-Yun Chen was born in Fujian Province, February, 1978. He obtained the bachelor's and doctor's degree in 2001 and 2006, respectively, both in University of Science and Technology of China. He is now an associate researcher of USTC. He is devoted to the study of the optical fiber based quantum communication with quantum cryptography system and network.Until now, he has published many papers on the high-profile journals, including 9 Physical Review Letters, and 1 Physical Review X. His research work have been selected once as the "China's top ten science and technology news" by academicians of the Chinese Academy of Sciences and Chinese Academy of Engineering and "Highlights of the Year" by American Physical Society.
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Related Publications
- Experimental Mode-Pairing Measurement-Device-Independent Quantum Key Distribution without Global Phase Locking. Physical Review Letters 130, 030801 (2023).
- Field Test of Twin-Field Quantum Key Distribution through Sending-or-Not-Sending over 428 km. Physical Review Letters 126, 250502 (2021).
- Twin-field quantum key distribution over a 511 km optical fibre linking two distant metropolitan areas. Nature Photonics (2021). doi:10.1038/s41566-021-00828-5
- An integrated space-to-ground quantum communication network over 4,600 kilometres. Nature 589, 214-219 (2021).
- High-Speed Measurement-Device-Independent Quantum Key Distribution with Integrated Silicon Photonics. Physical Review X 10, 031030 (2020).
- Long-distance transmission of quantum key distribution coexisting with classical optical communication over weakly-coupled few-modefiber. Optics Express 28, (2020).
- Entanglement of two quantum memories via fibres over dozens of kilometres. Nature 578, 240-245 (2020).
- Experimentally Verified Approach to Nonentanglement-Breaking Channel Certification. Physical Review Letters 124, 1-6 (2020).
- Implementation of quantum key distribution surpassing the linear rate-transmittance bound. Nature Photonics 14, 422-425 (2020).
- Experimental Demonstration of High-Rate Measurement-Device-Independent Quantum Key Distribution over Asymmetric Channels. Physical Review Letters 122, 160501 (2019).