Multiparty quantum secret conference based on quantum encryption with pure entangled states 被引量：1

Multiparty quantum secret conference based on quantum encryption with pure entangled states

下载PDF

导出

摘要 We present a scheme for multiparty quantum remote secret conference （MQRSC） with pure entangled states, not maximally entangled multipartite quantum systems. The conferees first share a private quantum key, a sequence of pure entangled states and then use them to encode and decode the secret messages. The conferees exploit the decoy-photon technique to ensure the security of the transmission of qubits. This MQRSC scheme is more feasible and efficient than others. We present a scheme for multiparty quantum remote secret conference （MQRSC） with pure entangled states, not maximally entangled multipartite quantum systems. The conferees first share a private quantum key, a sequence of pure entangled states and then use them to encode and decode the secret messages. The conferees exploit the decoy-photon technique to ensure the security of the transmission of qubits. This MQRSC scheme is more feasible and efficient than others.

作者顾斌李传起陈玉林

机构地区 College of Math and Physics

出处《Chinese Physics B》 SCIE EI CAS CSCD 2009年第6期2137-2142,共6页 中国物理B（英文版）

基金 Project supported by the National Natural Science Foundation of China (Grant No 10847147) the Natural Science Foundation of Jiangsu Province (Grant No BK2008437) Jiangsu Provincial Universities (Grant No 07KJB510066) the Science Foundation of Nanjing University of Information Science and Technology

关键词 quantum secret conference pure entangled states quantum encryption quantum secret conference, pure entangled states, quantum encryption

分类号 O413.1 [理学—理论物理] TP309.7 [自动化与计算机技术—计算机系统结构]

引文网络
相关文献

参考文献64

1Gisin N, Ribordy G, Tittel W and Zbinden H 2002 Rev. Mod. Phys. 74 145
2Bennett C H and Brassad G 1984 Proc. IEEE Int. Conf. on Computers, Systems and Signal Processing, Bangalore, India (New York: IEEE) p175
3Long G L and Liu X S 2002 Phys. Rev. A 65 032302
4Hwang W Y 2003 Phys. Rev. Lett. 91 057901
5Deng F G and Long G L 2003 Phys. Rev. A 68 042315
6Deng F G and Long G L 2004 Phys. Rev. A 70 012311
7Lo H K, Chau H F and Ardehali M 2005 J. Cryptology 18 133
8Li X H, Deng F C and Zhou H Y 2008 Phys. Rev. A 78 022321
9Li X H, Deng F G and Zhou H Y 2007 Appl. Phys. Lett. 91 144101
10Hillery M, Buzek V and Berthiaume A 1999 Phys. Rev. A 59 1829

同被引文献10

1ZHANG Jingfu1, XIE Jingyi2, WANG Chuan1, DENG Zhiwei3, LU Zhiheng4, & LONG Guilu1,5 1. Key Laboratory For Quantum Information and Measurements of MOE, Department of Physics, Tsinghua University, Beijing 100084,China,2. Department of Materials Science and Engineering, Beijing Normal University, Beijing 100875, China,3. Testing and Analytical Center, Beijing Normal University, Beijing 100875,China,4. Department of Physics, Beijing Normal University, Beijing 100875, China,5. Key Laboratory For atomic and Molecular Nanosciences, Tsinghua University, Beijing 100084,China.Implementation of a multiple round quantum dense coding using nuclear magnetic resonance[J].Science China(Physics,Mechanics & Astronomy),2005,48(6):706-715. 被引量：8
2章礼华,董萍,曹卓良.Scheme for entanglement concentration of unknown W class states via linear optics[J].Chinese Physics B,2007,16(3):640-643. 被引量：6
3LI ChunYan1,2,LI XiHan1,2,DENG FuGuo1,2,3,ZHOU Ping1,2 & ZHOU HongYu1,2,3 1 Key Laboratory of Beam Technology and Material Modification of Ministry of Education,Beijing Normal University,Beijing 100875,China,2 Institute of Low Energy Nuclear Physics,and Department of Material Science and Engineering,Beijing Normal University,Beijing 100875,China,3 Beijing Radiation Center,Beijing 100875,China.Complete multiple round quantum dense coding with quantum logical network[J].Chinese Science Bulletin,2007,52(9):1162-1165. 被引量：5
4李熙涵,段晓礁,盛宇波,周宏余,邓富国.Faithful quantum entanglement sharing based on linear optics with additional qubits[J].Chinese Physics B,2009,18(9):3710-3713. 被引量：2
5顾斌,李传起,徐飞,陈玉林.High-capacity three-party quantum secret sharing with superdense coding[J].Chinese Physics B,2009,18(11):4690-4694. 被引量：2
6YAN FengLi1,2 & YAN Tao1,2 1 College of Physics Science and Information Engineering,Hebei Normal University,Shijiazhuang 050016,China,2 Hebei Advanced Thin Films Laboratory,Shijiazhuang 050016,China.Probabilistic teleportation via a non-maximally entangled GHZ state[J].Chinese Science Bulletin,2010,55(10):902-906. 被引量：14
7YAN Tao,YAN FengLi.Quantum key distribution using four-level particles[J].Chinese Science Bulletin,2011,56(1):24-28. 被引量：8
8顾斌,黄余改,方夏,张成义.A two-step quantum secure direct communication protocol with hyperentanglement[J].Chinese Physics B,2011,20(10):66-70. 被引量：17
9任宝藏,华明,李涛,杜芳芳,邓富国.Multipartite entanglement concentration of electron-spin states with CNOT gates[J].Chinese Physics B,2012,21(9):88-93. 被引量：1
10周澜,盛宇波,赵生妹.Optimal entanglement concentration for three-photon W states with parity check measurement[J].Chinese Physics B,2013,22(2):97-104. 被引量：2

引证文献1

1SHENG YuBo,LIU Jiong,ZHAO ShengYang,ZHOU Lan.Multipartite entanglement concentration for nitrogen-vacancy center and microtoroidal resonator system[J].Chinese Science Bulletin,2013,58(28):3507-3513. 被引量：10

二级引证文献10

1连汉丽.Loschmidt Echo of a central spin coupled to an XY spin chain:The role of the Dzyaloshinsky-Moriya interaction[J].Chinese Physics C,2014,38(7):40-44.
2Yan Chang,Shibin Zhang,Lili Yan,Jian Li.Deterministic secure quantum communication and authentication protocol based on three-particle W state and quantum one-time pad[J].Chinese Science Bulletin,2014,59(23):2835-2840. 被引量：3
3SHI Xuan,WEI LianFu,OH Choo Hiap.Quantum computation with surface-state electrons by rapid population passages[J].Science China(Physics,Mechanics & Astronomy),2014,57(9):1718-1724. 被引量：1
4DU FangFang,DENG FuGuo.Heralded entanglement concentration for photon systems with linear-optical elements[J].Science China(Physics,Mechanics & Astronomy),2015,58(4):16-23. 被引量：6
5MAIMAITI Wulayimu,LI Zhe,CHESI Stefano,WANG YingDan.Entanglement concentration with strong projective measurement in an optomechanical system[J].Science China(Physics,Mechanics & Astronomy),2015,58(5):70-75. 被引量：3
6SHENG YuBo,PAN Jun,GUO Rui,ZHOU Lan,WANG Lei.Efficient N-particle W state concentration with different parity check gates[J].Science China(Physics,Mechanics & Astronomy),2015,58(6):55-65. 被引量：4
7Dong-Yang Cao Bi-Heng Liu Zhao Wang Yun-Feng Huang Chuan-Feng Li Guang-Can Guo.Multiuser-to-multiuser entanglement distribution based on 1550 nm polarization-entangled photons[J].Science Bulletin,2015,60(12):1128-1132. 被引量：10
8Chuan Wang,Wei-Wei Shen,Si-Chen Mi,Yong Zhang,Tie-Jun Wang.Concentration and distribution of entanglement based on valley qubits system in graphene[J].Science Bulletin,2015,60(23):2016-2021. 被引量：4
9赵培茈,许国富,仝殿民.非绝热和乐量子计算研究进展[J].科学通报,2021,66(16):1935-1945. 被引量：1
10常彦红,刘阿鹏.基于囚禁在双边光学微腔内的量子点自旋辅助的自避错纠缠浓缩[J].量子光学学报,2019,25(3):297-307. 被引量：2

1张光寅.信息高速公路,信息港与光子技术[J].微小型计算机开发与应用,1997(4):2-4.
2高飞,温巧燕,秦素娟,朱甫臣.基于对称密钥的量子公钥密码[J].中国科学（G辑）,2010,40(1):26-32. 被引量：2
3宋宜昌,余勇昌.网络安全与信息加密技术浅析[J].中国数据通信,2004,6(6):104-106. 被引量：2
4尹俊艳,赵跃龙.基于加密的网络安全技术[J].中国科技信息,2005(3):26-26. 被引量：2
5许胜男.量子计算机与量子加密[J].河北民族师范学院学报,2014,34(2):23-24. 被引量：1
6张国锋,李树深.量子信息学简介[J].复印报刊资料（中学物理教与学）,2009(7):60-63.
7张国锋,李树深.量子信息学简介[J].物理教学,2009(3):2-4.
8邓富国,李熙涵,李春燕,周萍,梁玉洁,周宏余.Multiparty Quantum Secret Report[J].Chinese Physics Letters,2006,23(7):1676-1679.
9阿里云联手中科院发布量子加密通信产品[J].中国信息安全,2015,0(10):103-103.
10吕锋,樊冰,吴丹雯.四种新型加密技术的比较研究[J].计算机应用研究,2002,19(11):5-7. 被引量：4

Chinese Physics B

2009年第6期

浏览历史

内容加载中请稍等...

Multiparty quantum secret conference based on quantum encryption with pure entangled states 被引量：1

参考文献64

同被引文献10

引证文献1

二级引证文献10

相关作者

相关机构

相关主题

浏览历史