Quantum Dialogue Without Information Leakage via Cavity QED

YE Tian-yu

doi:10.3788/gzxb20144303.0327001

[1] BEIGE A, ENGLERT B G, KURTSIEFER C, et al. Secure communication with a publicly known key［J］.Acta Physica Polonica A, 2002, 101: 357.

[2] BOSTROM K, FELBINGER T. Deterministic secure direct communication using entanglement［J］. Physical Review Letters, 2002, 89: 187902.

[3] DENG F G, LONG G L,LIU X S. Two-step quantum direct communication protocol using the Einstein-Podolsky-Rosen pair block［J］. Physical Review A, 2003, 68: 042317.

[4] CAI Q Y, LI B W. Improving the capacity of the Bostrom-Felbinger protocol［J］. Physical Review A, 2004, 69: 054301.

[5] WANG C, DENG F G, LONG G L. Multi-step quantum secure direct communication using multi-particle Green-Horne-Zeilinger state［J］. Optics Communications, 2005, 253(1-3): 15-20.

[6] YAN X, SONG H S. Controlled quantum secure direct communication using a non-symmetric quantum channel with quantum superdense coding［J］. Physics Letters A, 2007, 364(2): 117- 122.

[7] LIN S, WEN Q Y, GAO F, et al. Quantum secure direct communication with χ-type entangled states［J］.Physical Review A, 2008, 78: 064304.

[8] CHEN X B, WANG T Y, DU J Z, et al. Controlled quantum secure direct communication with quantum encryption［J］. International Journal of Quantum Information, 2008, 6(3): 543-551.

[9] CHEN X B, WEN Q Y, GUO F Z, et al. Controlled quantum secure direct communication with W state［J］. International Journal of Quantum Information,2008, 6(4): 899-906.

[10] HUANG W, WEN Q Y, JIA H Y, et al. Fault tolerant quantum secure direct communication with quantum encryption against collective noise［J］.Chinese Physics B, 2012, 21(10): 100308.

[11] ZHANG Z J, MAN Z X. Secure direct bidirectional communication protocol using the Einstein-Podolsky-Rosen pair block［DB/OL］.［2013-06-13］.http://arxiv.org/pdf/quant-ph/0403215.pdf.

[12] ZHANG Z J, MAN Z X. Secure bidirectional quantum communication protocol without quantum channel［DB/OL］.［2013-06-13］.http://arxiv.org/pdf/quant-ph/0403217.pdf.

[13] ZHANG Z J, MAN Z X, LI Y. Economically improving message-unilaterally-transmitted quantum secure direct communication to realize two-way communication［DB/OL］.［2013-06-13］.http://arxiv.org/pdf/quant-ph/0406181.pdf.

[14] NGUYEN B A. Quantum dialogue［J］.Physics Letters A, 2004, 328(1): 6-10.

[15] MAN Z X, ZHANG Z J, LI Y. Quantum dialogue revisited［J］. Chinese Physics Letters,2005, 22(1): 22-24.

[16] JIN X R, JI X, ZHANG Y Q, et al. Three-party quantum secure direct communication based on GHZ states［J］. Physics Letters A, 2006, 354(1-2): 67-70.

[17] MAN Z X, XIA Y J. Controlled bidirectional quantum direct communication by using a GHZ state［J］. Chinese Physics Letters, 2006, 23(7): 1680-1682.

[18] MAN Z X, XIA Y J, NGUYEN B A. Quantum secure direct communication by using GHZ states and entanglement swapping［J］. Journal of Physics B, 2006, 39: 3855-3863.

[19] MAN Z X, XIA Y J.Improvement of security of three-party quantum secure direct communication based on GHZ states［J］. Chinese Physics Letters, 2007, 24(1): 15-18.

[20] CHEN Y, MAN Z X, XIA Y J. Quantum bidirectional secure direct communication via entanglement swapping［J］.Chinese Physics Letters, 2007, 24(1): 19-22.

[21] YANG Y G, WEN Q Y. Quasi-secure quantum dialogue using single photons［J］.Science in China Series G, 2007, 50(5): 558-562.

[22] GAO F, QIN S J, WEN Q Y, et al. Comment on: Three-party quantum secure direct communication based on GHZ states［J］. Physics Letters A, 2008, 372(18): 3333-3336.

[23] GAO F, GUO F Z, WEN Q Y, et al. Revisiting the security of quantum dialogue and bidirectional quantum secure direct communication［J］. Science in China Series G, 2008, 51(5): 559-566.

[24] SHAN C J, LIU J B, CHENG W W, et al. Bidirectional quantum secure direct communication in driven cavity QED［J］. Modern Physics Letters B, 2009, 23(27): 3225-3234.

[25] YE T Y, JIANG L Z. Improvement of controlled bidirectional quantum direct communication using a GHZ state［J］. Chinese Physics Letters, 2013, 30(4): 040305.

[26] LIU Z H, CHEN H W. Comment on “Improvement of controlled bidirectional quantum direct communication using a GHZ state”［J］.Chinese Physics Letters,2013, 30(7): 079901.

[27] YE T Y, JIANG L Z. Reply to the comment on “Improvement of controlled bidirectional quantum direct communication using a GHZ state”［J］.Chinese Physics Letters,2013, 30(7): 079902.

[28] SHI G F, XI X Q, TIAN X L, et al. Bidirectional quantum secure communication based on a shared private Bell state［J］. Optics Communications, 2009, 282(12): 2460-2463.

[29] SHI G F, XI X Q, HU M L, et al. Quantum secure dialogue by using single photons［J］. Optics Communications, 2010, 283(9): 1984-1986.

[30] SHI G F. Bidirectional quantum secure communication scheme based on Bell states and auxiliary particles［J］. Optics Communications, 2010, 283(24): 5275-5278.

[31] GAO G. Two quantum dialogue protocols without information leakage［J］. Optics Communications, 2010, 283(10): 2288-2293.

[32] YE T Y, JIANG L Z. Information leakage prevention in quantum dialogue using the measurement correlation after entanglement swapping and decreasing the transmission efficiency［J］. Acta Photonica Sinica, 2013, 42(11): 1311-1318.

[33] SHAN C J, LIU J B, CHEN T, et al. Controlled quantum secure direct communication with local separate measurements in cavity QED［J］. International Journal of Theoretical Physics,2010, 49: 334-342.

[34] ZHENG S B. Generation of entangled states for many multilevel atoms in a thermal cavity and ions in thermal motion［J］. Physical Review A, 2003, 68: 035801.

[35] ZHENG S B, GUO G C. Efficient scheme for two-atom entanglement and quantum information processing in cavity QED［J］. Physical Review Letters, 2000, 85(11): 2392-2395.