南京邮电大学量子信息处理实验室

Quantum Information Processing Laboratory, Nanjing University of Posts and Telecommunications

2025

  1. J. L. Zhu, X. Y. Zhou, H. J. Ding, J. Y. Liu, C. H. Zhang, J. Li. J. M. An, and Q. Wang. One-decoy-state quantum key distribution with advantage distillation based on planar-lightwave-circuit-integration modules, Phys. Rev. A 111, 012608 (2025).

  2. X. Y. Zhou, J. R. Hu, C. H. Zhang and Q. Wang. Optimization analysis for the maximum pairing length of mode-pairing quantum key distribution, Opt. Lett. 50, 249-252 (2025).

2024

  1. J. X. Xu, X. Ma, J. Y. Liu, C. H. Zhang, H. W. Li, X. Y. Zhou, Q. Wang. Automatically identifying imperfections and attacks in practical quantum key distribution systems via machine learning, Sci. China Inf. Sci. 67, 202501 (2024).

  2. X. Y. Zhou, J. R. Hu, J. J. Wang, Y. Cao,  C. H. Zhang, J. Li, and Q. Wang. Enhancing the performance of mode-pairing quantum key distribution by wavelength division multiplexing, Opt. Express 32, 18366-18378 (2024).

  3. D. Ding,H. R. Shen, Z. N. Lu, J. Li, and Q. Wang. Improving the performance of depth estimation with the rising edge fitting method, Opt. Express. 32. 42455-42465 (2024).

  4. L. Zhan, C. H. Zhang, N. Lu, X. R. Qian, H. J. Ding, J. Y. Liu, X. Y. Zhou, and Q. Wang. Experimental quantum digital signature based on heralded single-photon sources, Quantum Inf Process 23, 25 (2024).

  5.    M. Lu, J. H. Shi, J. Li, H. R. Shen, H. Y. Wang, C. Zhang, P. Z. Wang and Q. Wang. Enhancing the performance of point cloud completion assisted with tactile information,  J Image Video Proc. 2024, 43 (2024).

  6. J. l. Zhu, Y. Cao, M. X. Guo, X. Y. Zhou, C. H. Zhang, J. Li, X. S. Yu, Y. L.  Zhao, J. Zhang, and Q. Wang. Multi-protocol updating for seamless key negotiation in quantum metropolitan networks,J. Opt. Commun. Netw. 16, 735-749 (2024).

  7. M. S. Sun, C. H. Zhang, R. Zhang , X. Y. Zhou, J. Li  and Q. Wang. Improved model on asynchronous measurement-device-independent quantum key distribution with realistic devices, Chinese Phys. B 33 110302 (2024).

  8. 马洛嘉, 丁华建, 陈子骐, 张春辉, 王琴,一种态制备误差容忍的量子数字签名协议, 物理学报, 73(2): 020301 (2024).

2023

  1. J. Y. Liu, Q. Y. Jiang, H. J. Ding, X. Ma, M. S. Sun, J. X. Xu, C.-H. Zhang, S. Xie, J. Li, G. G. Zeng, X. Y. Zhou,Q. Wang. Highly efficient twin-field quantum key distribution with neural networks, Sci. China Inf. Sci. 66, 189402 (2023).

  2. H. J. Ding, J. Y. Liu, X. Y. Zhou, C.-H. Zhang, J. Li, and Q. Wang. Improved Finite-Key Security Analysis of Measurement-Device-Independent Quantum Key Distribution Against a Trojan-Horse Attack, Phys. Rev. Applied. 19, 044022 (2023).

  3. M. S. Sun, C. H. Zhang, H. J. Ding, X. Y. Zhou, J. Li, and Q. Wang.Practical Decoy-State Memory-Assisted Measurement-Device-Independent Quantum Key Distribution, Phys. Rev. Applied 20, 024029 (2023).

  4. M. S. Sun, W. L. Wang, X. Y. Zhou, C. H. Zhang, and Q. Wang.Source monitoring twin-field quantum key distribution assisted with Hong-Ou-Mandel interference,Phys. Rev. Research 5, 043179 (2023).

  5. H. J. Ding, X. Ma, J. Y. Liu, C. H. Zhang, X. Y. Zhou, and Q. Wang.Boosting the performance of loss-tolerant measurement-device-independent quantum key distribution, Opt.Lett.48,2797-2800 (2023).

  6. A.P. Liu, J.W. Liu, Z.F. Kang, G.J. Chen, X.B. Xu, X.F. Ren, G.C. Guo, Q. Wang, and C.L. Zou. Proposal of a free-space-to-chip pipeline for transporting single atoms,Phys. Rev. A 108, 033108 (2023).

  7. J. Y. Liu, X. Ma, H. J. Ding, C.-H. Zhang, X. Y. Zhou, and Q. Wang.Experimental demonstration of five-intensity measurement-device-independent quantum key distribution over 442 km, Phys. Rev. A 108, 022605 (2023).

  8. W. L. Wang, X. Y. Zhou, M. S. Sun, C. H. Zhang, Q. Wang. Side-Channel Free Measurement-Device-Independent Quantum Key Distribution Based on Source Monitoring,IEEE Photonics Journal 15, 5 (2023).

  9. T. Wu, C.  H. Zhang, X.  Y. Zhou, J. Li and Q. Wang,  Measurement-Device-Independent Quantum Random-Number Generator With Source Flaws,IEEE Photonics Journal 15,6 (2023).

  10. 朱佳莉,曹原,张春辉,王琴. 实用化量子密钥分发光网络中的资源优化配置, 物理学报 72, 020301 (2023).

  11. 刘天乐,徐枭,付博伟,徐佳歆,刘靖阳,周星宇,王琴. 基于回归决策树的测量设备无关型量子密钥分发参数优化物理学报 72, 110304 (2023).

2022

  1. A.P. Liu, W, Peng, Z.R. Li, X.P. Zhou, X.F. Ren, C.L. Zou, Q. Wang; On-chip converter of waveguide polarization mode to free-space optical angular momentum mode, Appl. Phys. Lett. 12 (2022).

  2. M. Wei, C. H. Zhang, J.  Li, J.  L. Zhu and Q. Wang. Experimental demonstration of tomography-based quantum key distribution, Optics Letters. 47, 6285 (2022).

  3. H. J. Ding, X. Y. Zhou, C. H. Zhang, J. Li and Q. Wang. Measurement-device-independent quantum key distribution with insecure sources, Optics Letters. 47, 665 (2022).

  4. W. Fang, J. Li, M. Wei, C. H. Zhang and Q. Wang. Proof-of-principle demonstration of sequential 3 → 1 quantum random access code via cascaded measurements, Optics Express. 30, 8126 (2022).

  5. Y. H. Chen, J. Li, S. P. Xie, Q. Wang. Single-photon 3D imaging with a multi-stage network, Optics Express. 30, 29173 (2022)

  6. M. S. Sun, C. H. Zhang, X. Ma, X. Y. Zhou and Q. Wang. Sending-or-not-sending twin-field quantum key distribution with measurement imperfections, IEEE Communications Letters. (2022).

  7. A. P. Liu, J. W. Liu, W. Peng, X. B. Xu , G. J. Chen, X. F. Ren, Q. Wang, C. L. Zou. Multigrating design for integrated single-atom trapping, manipulation, and readout, Phys. Rev. A. 105, 053520 (2022).

  8. A. P. Liu, L. Xu, X. B. Xu, G. J. Chen, P. F. Zhang, G. Y. Xiang, G. C. Guo, Q. Wang, C. L. Zou. Proposal for low-power atom trapping on a GaN-on-sapphire chip, Phys. Rev. A. 106, 033104 (2022).

  9. B. X. Ji, J. Li and Q. Wang. Extracting More Quantum Randomness With Non-Uniform Quantization,  IEEE Photonics Journal. 14, 7647406 (2022).

  10. X. R. Qian, C. H. Zhang, H. W. Yuan, X. Y. Zhou, J. li, and Q. Wang. Passive light source monitoring for sending-or-not sending twin-field quantum key distribution, Entropy. 24, 592 (2022).

  11. Y. Y. Zhou, X. P. Zhou, R. Zhuang, A. P. Liu and Q. Wang. Near-infrared broadband polarization beam splitter with an Au nanocube array, Physica Scripta. 97, 115507 (2022).

  12. J. X. Xu, Z. A. Ren, Y. P. Chen, C. H. Zhang and Q. Wang. Optimal resource allocation of quantum digital signatures with machine learning, Quantum Inf Process. 21, 338 (2022).

  13. W. J. Wang, X. Y. Zhou, C. H. Zhang, H. J. Ding and Q. Wang. Performance influence on reference-frame-independent quantum key distributions with detection imperfections, Quantum Inf Process. 21, 283 (2022).

  14. Z. D. Liao, Z. Lu, J. Li and Q. Wang. Robust 3D imaging based on regularization by denoising, JOSAA. 39, 2001 (2022).

  15. G. L. Piao, H. W. Yuan, C. H. Zhang, X. Ma, H. J. Ding, X. Y. Zhou, J. Li, and Q. Wang. Passive blind quantum computation with heralded single-photon sources,  J. Opt. Soc. Am. B. 39, 2020 (2022).

  16. J. J. Hong, X. P. Zhou, R. Zhuang, W. Peng, J. W. Liu, A. P. Liu, Q. Wang. Nanoparticle trapping by counter-surface plasmon polariton lens, Chinese Optics Letters. 20, 023601(2022).

  17. 刘爱萍,陈广杰,陈梁,徐新标,张延磊,王琴,邹长铃. 集成光子-原子芯片的研究进展(特邀), 光子学报 51, 0551302 (2022).

  18.  陈以鹏,刘靖阳,朱佳莉,方伟,王琴. 机器学习在量子通信资源优化配置中的应用, 物理学报 71, 220301 (2022).

2021

  1. X. Y. Zhou, H. J. Ding, M. S. Sun, S. H. Zhang, J. Y. Liu, C. H. Zhang, J. Li, Q. Wang. Reference-Frame-Independent Measurement-Device-Independent Quantum Key Distribution Over 200 km of Optical Fiber, Phys. Rev. Applied. 15, 064016 (2021).

  2. J. Y. Liu, X. Y. Zhou, C. H. Zhang, H. J. Ding, Y. P. Chen, J. Li, Q. Wang. Boosting the performance of reference-frame-independent measurement-device-independent quantum key distribution, J. Lightwave Technol. 39, 5486 (2021)            

  3. C. H. Zhang, X. Y. Zhou, C. M Zhang, J. Li, Q. Wang. Twin-field quantum digital signatures, Opt. Lett. 46, 3757 (2021)

  4. Y. P. Chen, J. Y. Liu, M. S. Sun, X. Y. Zhou, C. H. Zhang, J. Li, Q. Wang. Experimental measurement-device-independent quantum key distribution with the double-scanning method, Opt.Lett. 46,3729 (2021)

  5. J. Y. Liu, X. Y. Zhou and Q. Wang. Reference-frame-independent measurement-device-independent quantum key distribution using fewer states, Phys. Rev. A. 103, 022602 (2021)

  6. Z. G. Pang, J. Gao, T. L. Hou, M. Wei, J. Li and Q. Wang. Sequential 3 → 1 quantum random access code utilizingunsharp measurements, Chinese Optics Letters. 19 112701 (2021)

  7. S. H. Zhang, J. Y. Liu, G. G. Zeng, C. H. Zhang, X. Y. Zhou and Q. Wang. Machine Learning-Assisted Measurement Device-IndependentQuantum Key Distribution on Reference Frame Calibration, Entropy. 23 1242 (2021)

  8. Z. A. Ren, Y. P. Chen, J. Y. Liu, H. J.Ding and Q. Wang. Implementation of Machine Learning in Quantum Key Distributions., IEEE Commun. Lett. 25, 940 (2021).

  9. J. Wang, C. H. Zhang, J. Y. Liu, X. R. Qian, J. Li, Q. Wang. Improving the purity of heralded single-photon sources through spontaneous parametric down-conversion process, Chin. Phys. B. 30, 070304 (2021)

  10. X. K. li, X. Q. Song, Q. W. Guo, X. Y. Zhou, Q. Wang. Practical decoy-state BB84 quantum key distribution with quantum memory, Chin. Phys. B. 30, 060305 (2021)


2020

  1. X. Y. Zhou, H. J. Ding, C. H. Zhang, J. Li, C. M. Zhang and Q. Wang. Experimental Three-State Measurement-Device-Independent Quantum Key Distribution with Uncharacterized Sources, Opt. Lett, 45,4176(2020)

  2. H. J. Ding, J. J. Chen, L. Ji, X. Y. Zhou, C. H. Zhang, C. M. Zhang and Q. Wang,280-km experimental demonstration of a quantum digital signature with one decoy state, Opt. Lett.45,1711(2020).

  3. A. P. Liu, M. Z. Wu, R. Zhuang, J. J. Hong, Q. Wang and X. F. Ren,On-chip generation of the reconfigurable orbital angular momentum with high order, Opt. Express 28,12(2020)

  4. Y. Wang, J Li, X. R. Wang, T. J. Liu and Q. Wang,Experimental demonstration of hidden nonlocality with local filters, Opt. Express 28,9(2020)

  5. S. S. Han, H. J. Ding, C. H. Zhang, X. Y. Zhou, C. M. Zhang and Q. Wang. Practical decoy-state quantum random number generator with weak coherent sources, Quantum Information Processing 19,396(2020).

  6. W. Z. Wu, J. R. Zhu, L, Ji , C. M. Zhang and Q. Wang, Proof-of-principle demonstration of decoy-state quantum key distribution with biased basis choices, Quantum Information Processing 19,341(2020).

  7. C. M. Zhang, Y. Zhu, J. J. Chen and Q. Wang, Practical quantum digital signature with configurable decoy states, Quantum Information Processing 19,151(2020).

  8. H. J. Ding, J. Y. Liu, C. M. Zhang and Q. Wang, Predicting optimal parameters with random forest for quantum key distribution, Quantum Information Processing 19,60(2020).

  9. J. J. Chen, C. H. Zhang, J. M. Chen, C. M. Zhang and Q. Wang, Improving the performance of decoy-state quantum digital signature with single-photon-added coherent sources, Quantum Information Processing, 19,198(2020).

2019

  1. J. Y. Liu, H. J. Ding, C. M. Zhang, S. P. Xie, and Q. Wang,Practical Phase-Modulation Stabilization in Quantum Key Distribution via Machine Learning , Phys. Rev. Applied. 12, 014059 (2019).

  2. X. Y. Zhou, C. H. Zhang, C. M. Zhang, and Q. Wang, Asymmetric sending or not sending twin-field quantum key distribution in practice,Phys. Rev. A 99, 062316 (2019).

  3. C. H. Zhang, C. M. Zhang, and Q. Wang,Efficient passive measurement-device-independent quantum key distribution,Phys. Rev. A 99, 052325 (2019)

  4. X. R. Wang,L. Y. Wu,C. X. Liu,T. J. Liu,J. Li,and Q Wang, Experimental generation of entanglement-assisted quantum random access code , Phys. Rev. A 99, 052313 (2019)

  5. J. Li,T. J. Liu,S. Wang,C. Jebarathinam,and Q Wang,Experimental violation of Mermin steering inequality by three-photon entangled states with nontrivial GHZ-fidelity , Opt. Express. 27, 013559 (2019)

  6. J. R. Zhu,W. Z. Wu, ,L. Ji,C. M. Zhang and Q. Wang,Experimental quantum key distribution with uncharacterized sources and projective measurements ,Opt. Lett. 44, 5703(2019)

  7. C. H. Zhang,C. M. Zhang, and Q. Wang,Twin-field quantum key distribution with modified coherent states,Opt. Lett.  44, 1468 (2019)

  8. C. M. Zhang,W. B. Wang,H. W. Li,Q. Wang,Weak randomness impacts the security of reference-frame-independent quantum key distribution, Opt. Lett.44, 1226 (2019).

  9. X. B. An, H. Zhang, C. M. Zhang, W. Chen, S. Wang, Z. Q. Yin, Q. Wang, D. Y. He, P. L. Hao, S. F. Liu, X. Y. Zhou, G. C. Guo, and Z. F. Han,Practical quantum digital signature with a gigahertz BB84 quantum key distribution system, Opt. Lett. 44(2019).

  10. S. Wang, C. X. Liu, J. Li, Q. Wang, Research on the Hong-Ou-Mandel interference with two independent sources. Scientific Reports , 2019, 9(1): 3854.

  11. X. Y. Zhou,C. M. Zhang, G. C. Guo,Q Wang,Improved Decoy-State Measurement-Device-Independent Quantum Key Distribution With Imperfect Source Encoding , IEEE PHOTONICSJ, 11(2019)

  12. H. Zhang, C. H. Zhang, C. M. Zhang, G. C. Guo, Q. Wang, Enhanced measurement-device-independent quantum key distribution in reference-frame-independent scenario, J. Opt. Soc. Am. B, 36, 476 (2019).

  13. C. X. Liu, J. Li, T. J. Liu, X. R. Wang, S. Wang, and Q. Wang, Experimental realization of more quantum randomness generation based on non-projective measurements. J. Phys. B: At. Mol. Opt. Phys.52145501.

  14. H. Zhang, X. B .An,C. M. Zhang,Q. Wang,High-efficiency quantum digital signature scheme for signing long messages , Quantum Inf Process,18,(2019) .

  15. C. C. Mao, C. H. Zhang, C. M. Zhang and Q. Wang, Improving the performance of four-intensity decoy-state measurement-device-independent quantum key distribution via heralded pair-coherent sources, Quantum Information Processing 18, 290 (2019).

2018

  1. C. H. Zhang, X. Y.  Zhou, H. J. Ding, C. M. Zhang, G. C. Guo, and Q. Wang,Proof-of-Principle Demonstration of Passive Decoy-State Quantum Digital Signatures Over 200 km,Phys.Rev.Appl 10, 034033 (2018)

  2. Z. B. Hou, J. F. Tang, J. W. Shang, H. J. Zhu, J. Li, Y. Yuan, K. D. Wu, G. Y. Xiang, C. F. Li and G. C. Guo,Deterministic realization of collective measurements via photonic quantum walks , Nat. Commun. 9, 1414 (2018).

  3. J. Li, C. Y. Wang, T. J. Liu and Q. Wang,Experimental verification of steerability via geometric Bell-like inequalities , Phys. Rev. A 97, 032107 (2018).

  4. C. C. Mao, X. Y. Zhou, J. R. Zhu, C. H. Zhang, C. M. Zhang and Q. Wang,Improved statistical fluctuation analysis for measurement-device-independent quantum key distribution with four-intensity decoy-state method , Opt. Express 26, 13289 (2018).

  5. A. P. Liu, C. L. Zou, X. F. Leng, W. He,M. Z .Wu, G. C. Guo and Q. Wang,Reconfigurable vortex beam generator based on the Fourier transformation principle , Opt. Express 31880-31888 (2018).

  6. C. H. Zhang, C. M. Zhang, G. C. Guo and Q. Wang, Biased three-intensity decoy-state scheme on the measurement-device-independent quantum key distribution using heralded single-photon sources, Opt. Express 26, 4219 (2018).

  7. C. H. Zhang, D. W, X. Y.  Zhou, S. Wang, L. B.  Zhang, Z. Q. Yin, W. Chen, Z. F. Han, G. C. Guo, and Q. Wang,Proof-of-principle demonstration of parametric down-conversion source-based quantum key distribution over 40 dB channel loss,Opt. Express 26, 25921 (2018)

  8. C. H. Zhang, D. Wang, C. M. Zhang and Q. Wang, A simple scheme for realizing the passive decoy-state quantum key distribution, J. Lightwave Technol., 36, 2868-2873 (2018).

  9. C. M. Zhang, J. R. Zhu and Q. Wang,Reference-Frame-Independent Measurement-Device-Independent Quantum Key Distribution With Modified Coherent States , IEEE Photonics Journal 10,7600608(2018)

  10. K. Liu, J. Wei, C. M. Zhang, and Q. Wang,  Passive decoy-state quantum key distribution with the SARG04 protocol,  J. Opt. Soc. Am. B 35, 1066-1071 (2018).

  11. H. J. Ding, C. C. Mao,C. M. Zhang,Q. Wang,Improved statistical fluctuation analysis for measurement-device-independent quantum key distribution , Quantum Inf Process, 17:332(2018) .

  12. J. R. Zhu, C. Y. Wang, K. Liu, C. M. Zhang, Q. Wang,Decoy-state reference-frame-independent quantum key distribution with the single-photon-added coherent source , Quantum Inf Process, 17:294(2018)

2017

  1. X. Y. Zhou, C. H. Zhang, C. M. Zhang, and Q. Wang, Obtaining better performance in the measurement-device-independent quantum key distribution with heralded single-photon sources, Phys. Rev. A 96, 052337 (2017).

  2. C.-M. Zhang, J.-R. Zhu, and Q. Wang, Practical decoy-state reference-frame-independent measurement-device-independent quantum key distribution, Phys. Rev. A 95, 032309 (2017).

  3. C. M. Zhang, J.-R. Zhu, and Q. Wang, Decoy-State Reference-Frame-Independent Measurement-Device-Independent Quantum Key Distribution With Biased Bases, J. Lightwave Technol., 35, 4574 (2017).

  4. T.-J. Liu, C.-Y. Wang, J. Li and Q. Wang, Experimental preparation of an arbitrary tunable Werner state, Europhys. Lett., 119, 14002 (2017).

  5. J. Wei, C. H. Zhang, and Q. Wang, New passive decoy-state quantum key distribution with thermal distributed parametric down-conversion source, Quantum Inf Process, 16, 50 (2017).

  6. C.-C. Mao, J. Li, J.-R. Zhu, C.-M. Zhang, and Q. Wang, An improved proposal on the practical quantum key distribution with biased basis, Quantum Inf Process, 16, 256 (2017).

  7. J.-R. Zhu, J. Li, C.-M. Zhang, and Q. Wang, Parameter optimization in biased decoy-state quantum key distribution with both source errors and statistical fluctuations, Quantum Inf Process, 16, 238 (2017).

  8. X. Y. Zhou, C. M. Zhang, and Q. Wang,Implementing full parameter optimization on decoy-state measurement-device-independent quantum key distributions under realistic experimental conditions , Journal of the Optical Society of America B, 34, 1518 (2017).

  9. G. C. Guo, H. Zhang and Q. Wang,Review on development of quantum information technology , JNUPT, 37(3), (2017).

2016

  1. Q. Wang, C. H. Zhang, X. B. Wang, Scheme for realizing passive quantum key distribution with heralded single-photon sources, Phys. Rev. A 93, 032312 (2016).

  2. Aiping Liu, Chang-Ling Zou, Xifeng Ren, Wang Qin, and Guo Guang-Can, On-chip generation and control of the vortex beam, Applied Physics Letters, 108,181103 (2016).

  3. Q. Wang, X. Y. Zhou, G. C. Guo, Realizing the measure-device-independent quantum-key-distribution with passive heralded-single photon sources, Scientific Reports 6, 35394 (2016).

  4. Q. Wang, C. H. Zhang, S-L. Luo, G-C. Guo, An enhanced proposal on decoy-state measurement device-independent quantum key distribution, Quantum Inf Process, 15, 3785 (2016).

  5. J.-R. Zhu, F. Zhu, X-Y. Zhou, Q. Wang, The enhanced measurement-device-independent quantum key distribution with two-intensity decoy states, Quantum Inf Process 15, 3799–3813 (2016).

  6. X. Y. Zhou, C. H. Zhang, G. C. Guo, Q. Wang, The statistical fluctuation analysis for the measurement-device-independent quantum key distribution with heralded single-photon sources, Quantum Inf. Process, 15, 2455 (2016).

2015

  1. C.H. Zhang, S.L. Luo, G.C. Guo, Q. Wang, Approaching the ideal quantum key distribution with two-intensity decoy state, Phys. Rev. A 92, 022332 (2015).

  2. D. Wang, M. Li, G.C. Guo, Q. Wang, An improved scheme on decoy-state method of measurement-device-independent quantum key distribution, Scientific Reports 5, 15130 (2015).

  3. F. Zhu, X. Y. Zhou, A.P. Liu, Q. Wang, A new scheme on improving the performance of the quantum key distribution with two-intensity weak coherent light, Quantum Inf Process, 14, 3773 (2015).

2014

  1. D. Wang, Q. Wang et al., Quantum key distribution with the single-photon-added coherent source, Phys. Rev. A 90, 062315 (2014).

  2. Aiping Liu, Chang-Ling Zou, Xifeng Ren, Xiao Xiong, Yong-Jing Cai, Haitao Liu, Fang-Wen Sun, Guang-Can Guo, Guo-Ping Guo, Independently analyzing different surface plasmon polariton modes on silver nanowire,Optics Express 22(19), 23372-23378 (2014).

  3. Q. Wang, X.B. Wang, Simulating of the measurement-device independent quantum key distribution with phase randomized general sources,Scientific Reports, 4, 4612 (2014).

  4. F. Zhu, Q. Wang, The quantum key distribution based on heralded single photon source, Acta Optica Sinica 34, 0627002 (2014).

2013

  1. Q. Wang and X.B. Wang, Efficient implementation of the decoy-state measurement-device-independent quantum key distribution with heralded single-photon sources, Phys. Rev. A 88, 052332 (2013).

2012年以前部分文章摘录:

  1. Q. Wang, W. Chen, G. Xavier, M. Swillo, T. Zhang, S. Sauge, M. Tengner, Z-F Han, G-C. Guo and A. Karlsson, Experimental Decoy-State Quantum Key Distribution with a Sub-Poissionian Heralded Single-Photon Source, Phys. Rev. Lett. 100, 090501 (2008).

  2. Q. Wang, S. Stobbe and P. Lodahl, Mapping the Local Density of Optical States of a Photonic Crystal with Single Quantum Dots, Phys. Rev. Lett. 107, 167404 (2011).

  3. Q. Wang, X-B Wang and G-C Guo, Practical decoy-state method in quantum key distribution with a heralded single-photon source, Phys. Rev. A 75, 012312 (2007).

  4. Q. Wang, F-W Sun, Y-S Zhang, J-Li, Y-F Huang and G-C Guo, Experimental demonstration of a method to realize weak measurement for the arrival time of a single photon, Phys. Rev. A 73, 023814 (2006).

  5. Q. Wang and A. Karlsson, Performance enhancement of decoy-state quantum key distribution using conditionally prepared down-conversion source in Poisson distribution, Phys. Rev. A 76,014309 (2007).

  6. Q. Wang, X-B Wang, G. Bjork and A. Karlsson, Improved practical decoy state method in quantum key distribution with parametric down-conversion source, Europhys. Lett. 79, 40001 (2007).

  7. Q. Wang, S. Stobbe, N. Thyrrestrup, H. Hofmann, M. Kamp, T. W. Schlereth, S. Hofling and P. Lodahl, Highly anisotropic decay rates of single quantum dots in photonic crystal membranes, Opt. Lett. 35, 162768 (2010).

  8. Q. Wang, Y-S Zhang, Y-F Huang and G-C Guo, Simulating the fourth-order interference phenomenon of anyons with photon pairs, Eur. Phys. J. D 42, 179 (2007).

  9. Q. Wang, M. Swillo and A. Karlsson, High intensity polarization entangled source with a 2D nonlinear photonic crystal, SPIE 7366, (2009).

  10. Q. Wang, Y-F Huang, F-W Sun, Y-S Zhang and G-C Guo, A “Which Way” Experiment of Two-Photon Interference, Chinese Physics Letter 22, 335 (2005).

  11. Q. Wang, Y-S Zhang, Y-F Huang and G-C Guo, Experimental demonstration of a simple method to engineer a single qutrit-state with biphotons, Phys. Lett. A 344, 29 (2005).

  12. Q. Wang and Y-S Zhang, Self-assembled quantum dot based quantum memory, Eur. Phys. J. B 85, 225 1-6 (2012).