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中国科学技术大学博士生导师教师师资介绍简介-张军

本站小编 Free考研考试/2021-04-21

张军
单位:合肥微尺度物质科学国家研究中心
地址:合肥市金寨路96号中国科技大学东区物质楼B楼1009室
邮编:230026
电话:**
个人主页: http://quantum.ustc.edu.cn
实验室介绍:


个人简历 Personal resume


张军,男,中国科学技术大学教授、博士生导师。 2002年、2007年分别获得中国科学技术大学学士、博士学位,2007年8月至2011年1月在瑞士日内瓦大学从事博士后研究,2011年1月起引进回国工作,2016年7月起任中国科学技术大学教授。长期从事量子通信、单光子探测及应用、量子随机数、量子激光雷达等方向的研究。实现InGaAs/InP单光子雪崩光电二极管核心元器件的国产化;提出并实现新型高速单光子探测门控方法,解决了单光子探测器工作频率的瓶颈问题;在国际上率先研制出板级集成、单片集成读出电路的实用化1.25 GHz单光子探测器,并在量子保密通信“京沪干线”项目中得到规模化部署,为干线的开通运行提供核心器件支撑;针对量子激光雷达、多光子纠缠与量子中继等系统的需求,研制低噪声近红外自由运行单光子探测器、超高效率硅单光子探测器等关键器件;提出并实现基于激光相位波动的超高速量子随机数产生方案,MIT Technology Review对此专门报道,核心技术专利荣获“中国专利优秀奖”。在Nature(2篇)、Nature Photonics(3篇)、Nature Physics(1篇)、Physical Review Letters(9篇)、Optica(4篇)、Optics Express(4篇)、Optics Letters(2篇)、Applied Physics Letters(2篇)、Physical Review A(8篇)等国际重要学术期刊上发表论文60篇,Google学术搜索引用次数达2750次,H因子为25。取得授权/受理发明专利15项。担任IET Quantum Communication期刊Associate Editor,担任ICEQT2019等国际会议组委会共主席。作为课题负责人承担国家重点研发计划重点专项项目,主持2项国家基金委面上项目以及其他科技项目。


研究方向 Research direction


1、量子通信
2、单光子探测/量子随机数
3、量子激光雷达



招生信息 Enrollment information


考生需要有良好的基础物理背景和实验动手能力,优先招收具有光通信、光电子、电子学等背景的考生


论文专著 The monograph Researcher ID


1)An integrated space-to-ground quantum communication network over 4,600 kilometres - Nature - 2021 -
2)Experimental Realization of Device-Independent Quantum Randomness Expansion - Physical Review Letters - 2021 -
3)Device-independent randomness expansion against quantum side information - Nature Physics - 2021 -
4)Single-photon imaging over 200 km - Optica - 2021 -
5)High detection efficiency silicon single-photon detector with a monolithic integrated circuit of active quenching and active reset - Review of Scientific Instruments - 2020 -
6)Single-photon computational 3D imaging at 45 km - Photonics Research - 2020 -
7)InGaAs/InP single-photon detectors with 60% detection efficiency at 1550 nm - Review of Scientific Instruments - 2020 -
8)Photonic realization of quantum resetting - Optica - 2020 -
9)Long-distance transmission of quantum key distribution coexisting with classical optical communication over a weakly-coupled few-mode fiber - Optics Express - 2020 -
10)Super-resolution single-photon imaging at 8.2 kilometers - Optics Express - 2020 -
11)Experimental demonstration of non-bilocality with truly independent sources and strict locality constraints - Nature Photonics - 2019 - 13, 687
12)Experimental quantum repeater without quantum memory - Nature Photonics - 2019 - 13, 644
13)Entanglement of three quantum memories via interference of three single photons - Nature Photonics - 2019 - 13, 210-213
14)Quantum Coherence Witness with Untrusted Measurement Devices - Physical Review Letters - 2019 - 123, 090502
15)Experimental nonlocal measurement of a product observable - Optica - 2019 - 6, 1199
16)Experimental 4-intensity decoy-state quantum key distribution with asymmetric basis-detector efficiency - Physical Review A - 2019 - 100, 042313
17)Compatibility of causal hidden-variable theories with a delayed-choice experiment - Physical Review A - 2019 - 100, 012114
18)Device-independent quantum random-number generation - Nature - 2018 - 562, 548
19)Miniaturized high-frequency sine wave gating InGaAs/InP single-photon detector - Review of Scientific Instruments - 2018 - 89, 123104
20)A monolithic readout circuit for high-frequency sine wave gating single-photon detection - Proc. SPIE - 2018 - 10825, 108251F
21)Compact and lightweight 1.5 μm lidar with a multi-mode fiber coupling free-running InGaAs/InP single-photon detector - Review of Scientific Instruments - 2018 - 89, 103106
22)Test of local realism into the past without detection and locality loopholes - Physical Review Letters - 2018 - 121, 080404
23)18-Qubit Entanglement with Six Photons’ Three Degrees of Freedom - Physical Review Letters - 2018 - 120, 260502
24)Phase amplification in optical interferometry with weak measurement - Physical Review A - 2018 - 97, 033851
25)Integrating quantum key distribution with classical communications in backbone fiber network - Optics Express - 2018 - 26, 6010
26)1.25 GHz sine wave gating InGaAs/InP single-photon detector with a monolithically integrated readout circuit - Optics Letters - 2017 - 42, 5090
27)Sine wave gating silicon single-photon detectors for multiphoton entanglement experiments - Review of Scientific Instruments - 2017 - 88, 083102
28)Fully integrated free-running InGaAs/InP single-photon detector for accurate lidar applications - Optics Express - 2017 - 25, 14611
29)Random Number Generation with Cosmic Photons - Phys. Rev. Lett. - 2017 - 118, 140402
30)Experimental measurement-device-independent quantum random number generation - Phys. Rev. A - 2016 - 94, 060301(R)
31)Design considerations of high-performance InGaAs/InP single-photon avalanche diodes for quantum key distribution - Applied Optics - 2016 - 55,7497
32)Fully integrated 3.2 Gbps quantum random number generator with real-time extraction - Rev. Sci. Instrum. - 2016 - 87, 076102
33)Advances in InGaAs/InP single-photon detector systems for quantum communication - Light: Science & Applications - 2015 - 4, e286
34)Simulation of a high-efficiency and low-jitter nanostructured silicon single-photon avalanche diode - Optica - 2015 - 2, 974
35)The generation of 68 Gbps quantum random number by measuring laser phase fluctuations - Rev. Sci. Instrum. - 2015 - 86, 063105
36)Long-range micro-pulse aerosol lidar at 1.5 μm with an upconversion single-photon detector - Optics Letters - 2015 - 40, 1579
37)Practical and fast quantum random number generation based on photon arrival time relative to external reference - Appl. Phys. Lett. - 2014 - 104, 051110
38)Fully integrated InGaAs/InP single-photon detector module with gigahertz sine wave gating - Rev. Sci. Instrum. - 2012 - 83, 083111
39)Entangled photons and quantum communication - Physics Reports - 2010 - 497, 1
40)32 bin near-infrared time-multiplexing detector with attojoule single-shot energy resolution - Rev. Sci. Instrum. - 2010 - 81, 103105
41)2.23 GHz gating InGaAs/InP single-photon avalanche diode for quantum key distribution - Proc. SPIE - 2010 - 7681, 76810Z
42)Photon Counting OTDR: Advantages and Limitations - IEEE Journal of Lightwave Technology - 2010 - 28, 952
43)Practical fast gate rate InGaAs/InP single-photon avalanche photodiodes - Appl. Phys. Lett. - 2009 - 95, 091103
44)Comprehensive Characterization of InGaAs/InP Avalanche Photodiodes at 1550 nm with an Active Quenching ASIC - IEEE J. Quantum Electron. - 2009 - 45, 792
45)Approaches to single photon detection - Nucl. Instrum. Meth. A - 2009 - 610, 16
46)Experimental high-intensity three-photon entangled source - Phys. Rev. A - 2008 - 78, 033819
47)General theory of decoy-state quantum cryptography with source errors - Phys. Rev. A - 2008 - 77, 042311
48)Experimental Long-Distance Decoy-State Quantum Key Distribution Based on Polarization Encoding - Phys. Rev. Lett. - 2007 - 98, 010505
49)Experimental quantum “Guess my Number” protocol using multiphoton entanglement - Phys. Rev. A - 2007 - 75, 022302
50)Experimental quantum communication without a shared reference frame - Phys. Rev. Lett. - 2006 - 96, 150504
51)Experimental fault-tolerant quantum cryptography in a decoherence-free subspace - Phys. Rev. A - 2006 - 73, 020301(R)
52)All-versus-nothing violation of local realism by two-photon, four-dimensional entanglement - Phys. Rev. Lett. - 2005 - 95, 240406
53)Experimental free-space distribution of entangled photon pairs over 13 km: towards satellite-based global quantum communication - Phys. Rev. Lett. - 2005 - 94, 150501



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