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Quantum Information Processing

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01-04-2019

Dissipative quantum repeater

Authors: M. Ghasemi, M. K. Tavassoly

Published in: Quantum Information Processing | Issue 4/2019

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Abstract

By implementing a quantum repeater protocol, our aim in this paper is the production of entanglement between two two-level atoms locating far from each other. To make our model close to experimental realizations, the atomic and field sources of dissipations are also taken into account. We consider eight of such atoms (\(1, 2, \ldots , 8\)) sequentially located in a line which begins (ends) with atom 1 (8). We suppose that initially the four atomic pairs \((i,i+1), i=1, 3, 5, 7,\) are mutually prepared in maximally entangled states. Clearly, the atoms 1, 8, the furthest atoms which we want to entangle them are never entangled, initially. To achieve the purpose of paper, at first, we perform the interaction between the atoms (2, 3) as well as (6, 7) which results in the entanglement creation between (1, 4) and (5, 8), separately. In the mentioned interactions, we take into account spontaneous emission rate (\(\varGamma \)) for atoms and field decay rate from the cavities (\(\kappa \)) as two important and unavoidable dissipation sources. In the continuation, we transfer the entanglement to the objective pair (1, 8) by two methods: (i) Bell state measurement and (ii) cavity quantum electrodynamics. The successfulness of our protocol is shown via the evaluation of concurrence as the well-established measure of entanglement between the two (far apart) qubits (1, 8). We also observe that if one chooses the cavity and the atom such that \(\kappa =\varGamma \) holds, the effect of dissipations is effectively removed from the entanglement dynamics in our model. In this condition, the time evolutions of concurrence and success probability are regularly periodic. Also, concurrence and success probability reach their maximum values in a large time interval by decreasing the detuning in the presence of dissipation.

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With (quantum) measurement (2, 3), for instance, we mean that one should operate the projection operator \(|eg \rangle \langle eg |\) (\(|ge \rangle \langle ge |\)) performed with the state \(|eg \rangle _{2, 3}\) (\(|ge \rangle _{2, 3}\)) on the state of particles (1, 2, 3, 4); the same is done for (6, 7).

Briegel, H.J., Dür, W., Cirac, J.I., Zoller, P.: Quantum repeaters: the role of imperfect local operations in quantum communication. Phys. Rev. Lett. 81(26), 5932 (1998)ADSCrossRef

Dür, W., Briegel, H.J., Cirac, J., Zoller, P.: Erratum: quantum repeaters based on entanglement purification. Phys. Rev. A 60(1), 725 (1999)ADSCrossRef

Duan, L.M., Lukin, M., Cirac, J.I., Zoller, P.: Long-distance quantum communication with atomic ensembles and linear optics. Nature 414(6862), 413 (2001)ADSCrossRef

Jiang, L., Muralidharan, S., Kim, J., Lutkenhaus, N., Lukin, M.: Ultrafast and fault-tolerant quantum communication over long distances. In: Frontiers in Optics, pp. FTu1A–1. Optical Society of America (2014)

Curty, M., Lewenstein, M., Lütkenhaus, N.: Entanglement as a precondition for secure quantum key distribution. Phys. Rev. Lett. 92(21), 217–903 (2004)CrossRef

Jennewein, T., Simon, C., Weihs, G., Weinfurter, H., Zeilinger, A.: Quantum cryptography with entangled photons. Phys. Rev. Lett. 84(20), 4729 (2000)ADSCrossRef

Hsieh, M., Kempe, J., Myrgren, S., Whaley, K.B.: An explicit universal gate-set for exchange-only quantum computation. Quantum Inf. Process. 2(4), 289–307 (2003)MathSciNetMATHCrossRef

Shi, J., Shi, R., Tang, Y., Lee, M.H.: A multiparty quantum proxy group signature scheme for the entangled-state message with quantum fourier transform. Quantum Inf. Process. 10(5), 653–670 (2011)MathSciNetMATHCrossRef

Moehring, D., Maunz, P., Olmschenk, S., Younge, K., Matsukevich, D., Duan, L.M., Monroe, C.: Entanglement of single-atom quantum bits at a distance. Nature 449(7158), 68 (2007)ADSCrossRef

10.

Bernien, H., Hensen, B., Pfaff, W., Koolstra, G., Blok, M., Robledo, L., Taminiau, T., Markham, M., Twitchen, D., Childress, L., et al.: Heralded entanglement between solid-state qubits separated by three metres. Nature 497(7447), 86 (2013)ADSCrossRef

11.

Hofmann, J., Krug, M., Ortegel, N., Gérard, L., Weber, M., Rosenfeld, W., Weinfurter, H.: Heralded entanglement between widely separated atoms. Science 337(6090), 72–75 (2012)ADSCrossRef

12.

Eghbali-Arani, M., Ameri, V.: Entanglement of two hybrid optomechanical cavities composed of bec atoms under bell detection. Quantum Inf. Process. 16(2), 47 (2017)ADSMathSciNetMATHCrossRef

13.

Zukowski, M., Zeilinger, A., Horne, M.A., Ekert, A.K.: Event-ready-detectors Bell experiment via entanglement swapping. Phys. Rev. Lett. 71, 4287–4290 (1993)ADSCrossRef

14.

Ghasemi, M., Tavassoly, M.K.: Entanglement swapping to a qutrit–qutrit atomic system in the presence of Kerr medium and detuning parameter. Eur. Phys. J. Plus 131(9), 297 (2016)CrossRef

15.

Ghasemi, M., Tavassoly, M.K., Nourmandipour, A.: Dissipative entanglement swapping in the presence of detuning and Kerr medium: Bell state measurement method. Eur. Phys. J. Plus 132(12), 531 (2017)CrossRef

16.

Nourmandipour, A., Tavassoly, M.K.: Entanglement swapping between dissipative systems. Phys. Rev. A 94(2), 022–339 (2016)CrossRef

17.

Nourmandipour, A., Tavassoly, M.K.: A novel approach to entanglement dynamics of two two-level atoms interacting with dissipative cavities. Eur. Phys. J. Plus 130(7), 148 (2015)CrossRef

18.

Liao, Q., Fang, G., Wang, Y., Ahmad, M., Liu, S.: Entanglement swapping in two independent Jaynes–Cummings models. Eur. Phys. J. D 61(2), 475–479 (2011)ADSCrossRef

19.

Haroche, S.: Cavity quantum electrodynamics: a review of Rydberg atom-microwave experiments on entanglement and decoherence. In: AIP Conference Proceedings, vol. 464, pp. 45–66. AIP (1999)

20.

Chun-Hua, Y., Yong-Cheng, O., Zhi-Ming, Z.: Entanglement swapping with atoms separated by long distance. Chin. Phys. 15(8), 1793 (2006)ADSCrossRef

21.

Yang, M., Zhao, Y., Song, W., Cao, Z.L.: Entanglement concentration for unknown atomic entangled states via entanglement swapping. Phys. Rev. A 71(4), 044–302 (2005)CrossRef

22.

Pakniat, R., Tavassoly, M.K., Zandi, M.H.: A novel scheme of hybrid entanglement swapping and teleportation using cavity QED in the small and large detuning regimes and quasi-Bell state measurement method. Chin. Phys. B 25(10), 100–303 (2016)CrossRef

23.

Pakniat, R., Tavassoly, M.K., Zandi, M.H.: Entanglement swapping and teleportation based on cavity QED method using the nonlinear atom-field interaction: cavities with a hybrid of coherent and number states. Opt. Commun. 382, 381–385 (2017)ADSCrossRef

24.

Jaynes, E.T., Cummings, F.W.: Comparison of quantum and semiclassical radiation theories with application to the beam maser. Proc. IEEE 51(1), 89–109 (1963)CrossRef

25.

Tavis, M., Cummings, F.W.: Exact solution for an N-moleculeradiation-field Hamiltonian. Phys. Rev. 170(2), 379 (1968)ADSCrossRef

26.

Di Fidio, C., Vogel, W., Khanbekyan, M., Welsch, D.G.: Photon emission by an atom in a lossy cavity. Phys. Rev. A 77(4), 043–822 (2008)CrossRef

27.

Di Fidio, C., Vogel, W.: Entanglement signature in the mode structure of a single photon. Phys. Rev. A 79(5), 050–303 (2009)CrossRef

28.

Man, Z., Xia, Y., An, N.: Quantum dissonance induced by a thermal field and its dynamics in dissipative systems. Eur. Phys. J. D 64(2–3), 521–529 (2011)ADSCrossRef

29.

Grünwald, P., Singh, S., Vogel, W.: Raman-assisted rabi resonances in two-mode cavity qed. Phys. Rev. A 83(6), 063–806 (2011)CrossRef

30.

Zhang, G.F., Xie, X.C.: Entanglement between two atoms in a damping Jaynes–Cummings model. Eur. Phys. J. D 60(2), 423–427 (2010)ADSCrossRef

31.

Baghshahi, H.R., Tavassoly, M.K., Behjat, A.: Entanglement of a damped non-degenerate \(\diamond \)-type atom interacting nonlinearly with a single-mode cavity. Eur. Phys. J. Plus 131(4), 80 (2016)

32.

Shore, B.W., Knight, P.L.: The Jaynes–Cummings model. J. Mod. Opt. 40(7), 1195–1238 (1993)ADSMathSciNetMATHCrossRef

33.

Barnett, S.M., Jeffers, J.: The damped Jaynes–Cummings model. J. Mod. Opt. 54(13–15), 2033–2048 (2007)ADSMATHCrossRef

34.

Luong, D., Jiang, L., Kim, J., Lütkenhaus, N.: Overcoming lossy channel bounds using a single quantum repeater node. Appl. Phys. B 122(4), 96 (2016)ADSCrossRef

35.

Li, L., Albert, V.V., Michael, M., Muralidharan, S., Zou, C., Jiang, L.: Quantum repeater with continuous variable encoding. In: APS Division of Atomic, Molecular and Optical Physics Meeting Abstracts (2016)

36.

Wang, T.J., Song, S.Y., Long, G.L.: Quantum repeater based on spatial entanglement of photons and quantum-dot spins in optical microcavities. Phys. Rev. A 85(6), 062–311 (2012)

37.

McMahon, P.L., De Greve, K.: Towards quantum repeaters with solid-state qubits: spin-photon entanglement generation using self-assembled quantum dots. In: Predojevic, A., Mitchell, M.W (eds) Engineering the Atom-Photon Interaction, Chap. 14, pp. 365–402. Springer (2015)

38.

Han, Yang, He, Bing, Heshami, Khabat, Li, Cheng-Zu, Simon, Christoph: Quantum repeaters based on Rydberg-blockade-coupled atomic ensembles. Phys. Rev. A 81(5), 052–311 (2010)CrossRef

39.

Zhao, Bo, Müller, Markus, Hammerer, Klemens, Zoller, Peter: Efficient quantum repeater based on deterministic Rydberg gates. Phys. Rev. A 81(5), 052–329 (2010)

40.

Van Meter, R., Ladd, T.D., Munro, W., Nemoto, K.: System design for a long-line quantum repeater. IEEE/ACM Trans. Netw. 17(3), 1002–1013 (2009)CrossRef

41.

Yuan, Z.S., Chen, Y.A., Zhao, B., Chen, S., Schmiedmayer, J., Pan, J.W.: Experimental demonstration of a BDCZ quantum repeater node. Nature 454(7208), 1098 (2008)ADSCrossRef

42.

Ladd, Thaddeus D., van Loock, Peter, Nemoto, Kae, Munro, William J., Yamamoto, Yoshihisa: Hybrid quantum repeater based on dispersive CQED interactions between matter qubits and bright coherent light. New J. Phys. 8(9), 184 (2006)ADSCrossRef

43.

Vollbrecht, Karl Gerd H., Muschik, Christine A., Cirac, J.Ignacio: Entanglement distillation by dissipation and continuous quantum repeaters. Phys. Rev. Lett. 107(12), 120–502 (2011)CrossRef

44.

Xu, P., Yong, H.L., Chen, L.K., Liu, C., Xiang, T., Yao, X.C., Lu, H., Li, Z.D., Liu, N.L., Li, L., et al.: Two-hierarchy entanglement swapping for a linear optical quantum repeater. Phys. Rev. Lett. 119(17), 170–502 (2017)CrossRef

45.

Chen, L.K., Yong, H.L., Xu, P., Yao, X.C., Xiang, T., Li, Z.D., Liu, C., Lu, H., Liu, N.L., Li, L., et al.: Experimental nested purification for a linear optical quantum repeater. Nat. Photonics 11(11), 695 (2017)ADSCrossRef

46.

Zheng, S.B., Guo, G.C.: Efficient scheme for two-atom entanglement and quantum information processing in cavity QED. Phys. Rev. Lett. 85(11), 2392 (2000)ADSCrossRef

47.

Ai-Xi, C., Li, D.: Entanglement swapping between atom and cavity and generation of entangled state of cavity fields. Chin. Phys. 16(4), 1027 (2007)ADSCrossRef

48.

Wootters, W.K.: Entanglement of formation of an arbitrary state of two qubits. Phys. Rev. Lett. 80(10), 2245 (1998)ADSMATHCrossRef

Title: Dissipative quantum repeater
Authors: M. Ghasemi
M. K. Tavassoly
Publication date: 01-04-2019
Publisher: Springer US
Published in: Quantum Information Processing / Issue 4/2019
Print ISSN: 1570-0755
Electronic ISSN: 1573-1332
DOI: https://doi.org/10.1007/s11128-019-2225-6

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