Coping with noise in joint remote preparation of a general two-qubit state by using nonmaximally entangled quantum channel

Dat Thanh Le, Hop Van Nguyen, An Ba Nguyen
Author affiliations

Authors

  • Dat Thanh Le Thang Long Institute of Mathematics and Applied Sciences,Hanoi
  • Hop Van Nguyen Hanoi National University of Education, Hanoi
  • An Ba Nguyen

DOI:

https://doi.org/10.15625/0868-3166/28/1/11722

Keywords:

joint remote state preparation, two-qubit state, noise

Abstract

Noise is unavoidable in practice and its presence makes quantum protocols imperfect. In this paper we consider a way to cope with typical types of noise in joint remote preparation of an arbitrary 2-qubit state. The idea is to use nonmaximally (in stead of maximally) entangled states as the initial quantum channel. Because noise changes the initial quantum channel we can beforehand tailor it to be nonmaximally entangled by introducing free parameters which, depending on given types of noise, can be controlled so that due to the affect of noise the initial quantum channel becomes closest to the maximally entangled one, thus optimizing the performance of the joint remote state preparation protocol. The dependence of the optimal averaged fidelities on the strength of various types of noise is represented by phase diagrams that clearly separate the quantum domain from the classical one.

Downloads

Download data is not yet available.

References

bibitem{i1} Y. Xia, J. Song and H. S. Song, textit{J. Phys. B: At. Mol. Opt. Phys.} textbf{40} (2007) 3719.

bibitem{i2} N. B. An and J. Kim, textit{J. Phys. B: At. Mol. Opt.

Phys.} textbf{41} (2008) 095501.

bibitem{i3} N. B. An and J. Kim, textit{Int. J. Quant. Inf.} textbf{6}

(2008) 1051.

bibitem{i4} A. K. Pati, textit{Phys. Rev. A} textbf{63} (2000) 014302.

bibitem{i5} N. B. An, textit{J. Phys. B: At. Mol. Opt. Phys.} textbf{%

} (2009) 125501.

bibitem{i6} K. Hou, J. Wang, Y. L. Lu and S. H. Shi, textit{Int. J. Theor.

Phys.} textbf{ 48} (2009) 2005.

bibitem{i7} M. X. Lou, X. B. Chen, S. Y. Ma, X. X. Niu and Y. X. Yang,

textit{Opt. Commun.} textbf{ 283} (2010) 4796.

bibitem{i8} Q. Q. Chen, Y. Xia, J. Song and N. B. An, textit{Phys. Lett. A}

textbf{374} (2010) 4483.

bibitem{i9} N. B. An, textit{Opt. Commun.} textbf{283} (2010) 4113.

bibitem{i10} N. B. An, C. T. Bich and N. V. Don, textit{Phys. Lett. A}

textbf{375} (2011) 3570.

bibitem{i11} N. B. An, C. T. Bich and N. V. Don, textit{J. Phys. B: At.

Mol. Opt. Phys.} textbf{44} (2011) 135506.

bibitem{i12} Q. Q. Chen, Y. Xia and N. B. An, textit{Opt. Commun.} textbf{%

} (2011) 2617.

bibitem{i13} Z. Y. Wang, textit{Int. J. Quant. Inf.} textbf{9} (2011) 809.

bibitem{i14} K. Hou, Y. B. Li, G. H. Liu and S. Q. Sheng, textit{J. Phys.

A: Math. Theor.} textbf{44} (2011) 255304.

bibitem{i15} X. Q. Xiao, J. M. Liu and G. Zeng, textit{J. Phys. B: At.

Mol. Opt. Phys.} textbf{44} (2011) 075501.

bibitem{i16} C. T. Bich, N. V. Don and N. B. An, textit{Int. J. Theor.

Phys.} textbf{51} (2012) 2272.

bibitem{i16a} Y. Xia, Q. Q. Chen and N. B. An, textit{J. Phys. A: Math. Theor.} textbf{45} (2012) 335306.

bibitem{i17} M. X. Luo, J. Y. Peng and Z. W. Mo, textit{Int. J. Theor.

Phys.} textbf{52} (2013) 644.

bibitem{i18} Y. B. Zhan and P. C. Ma, textit{Quant. Inf. Process.} textbf{%

} (2013) 997.

bibitem{i19} Y. B. Zhan, H. Fu, X. W. Li and P. C. Ma, textit{Int. J.

Theor. Phys.} textbf{52} (2013) 2615.

bibitem{i20} L. R. Long, P. Zhou, Z. Li and C. L. Yin, textit{Int. J.

Theor. Phys.} textbf{51} (2012) 2438.

bibitem{i21} D. Wang and L. Ye, textit{Int. J. Theor. Phys.} textbf{51}

(2012) 3376.

bibitem{i22} Y. M. Liao, P. Zhou, X. C. Qin and Y. H. He, textit{Quant.

Inf. Process.} textbf{13} (2014) 615.

bibitem{i23} M. X. Luo, X. B. Chen, Y. X. Yang and X. X. Niu, textit{%

Quant. Inf. Process.} textbf{ 11} (2012) 751.

bibitem{i24} R. F. Yu, Y. J. Lin and P. Zhou, textit{Quant. Inf. Process.}

textbf{15} (2016) 4785.

bibitem{esd} T. Yu and J. H. Eberly, textit{Phys. Rev. Lett.}

textbf{93} (2004) 140404; textit{Phys. Rev. Lett.} textbf{97} (2006)

bibitem{esd1} N. B. An and J. Kim, textit{Phys. Rev. A} textbf{79} (2009)

bibitem{i25} C. H. Bennett, G. Brassard, S. Popescu, B. Schumacher, J. A.

Smolin and W. K. Wooters, textit{Phys. Rev. Lett.} textbf{76} (1996) 722.

bibitem{i26} J. W. Pan, C. Simon, C. Brukner and A. Zeilinger, textit{%

Nature} textbf{410} (2001) 1067.

bibitem{i27} J. L. Romero, L. Roa, J. C. Retamal and C. Saavedra, textit{%

Phys. Rev. A} textbf{65} (2002) 052319.

bibitem{i29} Q. Sun, M. Al-Amri and M. S. Zubairy, textit{Phys. Rev. A}

textbf{80} (2009) 033838.

bibitem{i30} J. C. Lee, Y. C. Jeong, Y. S. Kim and Y. H. Kim, textit{Opt.

Express} textbf{19} (2011) 16309.

bibitem{i31} M. Hamada, textit{Phys. Rev. A} textbf{68} (2003) 012301.

bibitem{i32} T. Pramanik and A. S. Majumdar, textit{Phys. Lett. A} textbf{%

} (2013) 3209.

bibitem{i33} L. Qiu, G. Tang, X. Yang and A. Wang, textit{Ann. Phys.}

textbf{350} (2014) 137.

bibitem{i34} B. G. Taketani, F. de Melo and R. L. de Matos Filho, textit{%

Phys. Rev. A} textbf{85} (2012) 020301.

bibitem{i35} L. T. Knoll, Ch. T. Schmiegelow and M. A. Larotonda, textit{%

Phys. Rev. A} textbf{90} (2014) 042332.

bibitem{i36} P. Badziag, M. Horodecki, P. Horodecki and R. Horodecki,

textit{Phys. Rev. A} textbf{62} (2000) 012311.

bibitem{i37} S. Bandyopadhyay, textit{Phys. Rev. A} textbf{65} (2002)

bibitem{i38} Y. Yeo, textit{Phys. Rev. A} textbf{78} (2008) 022334.

bibitem{i39} R. Fortes and G. Rigolin, textit{Phys. Rev. A} textbf{92}

(2015) 012338.

bibitem{i40} H. Q. Liang, J. M. Liu, S. S. Feng, J. G. Chen and X. Y. Xu,

textit{Quant. Inf. Process.} textbf{14} (2015) 3857.

bibitem{i41} Z. F. Chen, J. M. Liu and L. Ma, textit{Chin. Phys. B}

textbf{23} (2014) 020312.

bibitem{i42} X. W. Guan, X. B. Chen, L. C. Wang and Y. X. Yang, textit{%

Int. J. Theor. Phys.} textbf{53} (2014) 2236.

bibitem{i43} M. M. Wang and Z. G. Qu, textit{Quant. Inf. Process.} textbf{%

} (2016) 4805.

bibitem{i44} H. Zhao and L. Huang, textit{Int. J. Theor. Phys.} textbf{56}

(2017) 720.

bibitem{i45} N. V. Hop, C. T. Bich and N. B. An, textit{Adv. Nat. Sci.:

Nanosci. Nanotech.} textbf{8} (2017) 015012.

bibitem{i46} K. Kraus, textit{States, Effects and Operators: Fundamental

Notions of Quantum Theory}, Springer-Verlag, Berlin, 1983.

bibitem{i47} M. A. Nielsen and I. L. Chuang, textit{Quantum Computation

and Quantum Information}, Cambridge University Press, Cambridge, 2000.

bibitem{i48} K. Zyczkowski and H. J. Sommers, textit{J. Phys. A: Math.

Gen.} textbf{34} (2001) 7111.

bibitem{i49} D. Bruss and C. Macchiavello, textit{Phys. Lett. A} textbf{%

} (1999) 249.

Downloads

Published

17-07-2018

How to Cite

[1]
D. T. Le, H. V. Nguyen, and A. B. Nguyen, “Coping with noise in joint remote preparation of a general two-qubit state by using nonmaximally entangled quantum channel”, Comm. Phys., vol. 28, no. 1, p. 1, Jul. 2018.

Issue

Vol. 28 No. 1 (2018)

Section

Invited Papers

License

Communications in Physics is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

Copyright on any research article published in Communications in Physics is retained by the respective author(s), without restrictions. Authors grant VAST Journals System (VJS) a license to publish the article and identify itself as the original publisher. Upon author(s) by giving permission to Communications in Physics either via Communications in Physics portal or other channel to publish their research work in Communications in Physics agrees to all the terms and conditions of https://creativecommons.org/licenses/by-sa/4.0/ License and terms & condition set by VJS.

Similar Articles

<< < 9 10 11 12 13 14 

You may also start an advanced similarity search for this article.