Effect of non-Markovian environment on quantum teleportation
via a two-qubit Heisenberg XXZ spin chain

Abstract

Abstract: The dynamic evolution of the average fidelity of quantum teleportation is investigated using quantum-state-diffusion (QSD) theory when two interacting qubits strongly coupled to a bosonic bath. The effects of environmental memory, anisotropic coupling parameters, Dzyaloshinskii-Moriya (DM) interaction and external magnetic field on quantum teleportation are analyzed and discussed. Results show that the memory effect of the environment can effectively improve the average fidelity. When the quantum channel is maximum entangled state, the optimal average fidelity can be obtained by increasing the coupling parameters, DM interaction or the external magnetic field. However, when the quantum channel is changed, the effect of the coupling constant between qubits on average fidelity is opposite. It indicates that the combination of the non-Markovian memory effect and optimal parameter can be used to achieve ideal quantum teleportation in theory.

Key words: quantum optics, non-Markovian environment, quantum state diffusion method, quantum teleportation

CLC Number:

O431.2

Dildar Hitjan, Arapat Ablimit, BAI Huiting, Aynisa Yasen, Aziza Abdukerem, Ahmad Abliz ∗. Effect of non-Markovian environment on quantum teleportation via a two-qubit Heisenberg XXZ spin chain[J]. Chinese Journal of Quantum Electronics, 2020, 37(6): 704-710.

References 24

[1]	Dirac P A M. Principles of Quantum Mechanics (量子力学原理) [M]. 4th ed., Trans by Ling Dongbo, et al. Beijing: Science
	Press, 2008 (in Chinese).
[2]	Bennett C H, Brassard G, Crepeau C, et al. Teleporting an unknown quantum state via dual classical and Einstein-Podolsky-
	Rosen channels [C]. Physical Review Letters, 1993, 70(13): 1895-1899.
[3]	Sajeev J, Tran Q. Localization of superradiance near a photonic band-gap [J]. Physical Review Letters, 1995, 74(17): 3419-
	3422.
[4]	Quang T,Woldeyohannes M, John S, et al. Coherent control of spontaneous emission near a photonic band edge: A single-atom
	optical memory device [J]. Physical Review Letters, 1997, 79(26): 5238-5241.
[5]	Breuer H P, Laine E M, Piilo J, et al. Colloquium : Non-Markovian dynamics in open quantum systems [J]. Reviews of Modern
	Physics, 2016, 88(2): 021002.
[6]	Zhang Yan. Studies on Quantum Correlation Dynamics of Three Qubits in Dissipative Environments (三耗散量子比特中的
	量子关联动力学研究) [D]. Shanghai: Master Thesis of East China Normal University, 2014 (in Chinese).
[7]	Lopez C E, Romero G, Lastra F, et al. Sudden birth versus sudden death of entanglement in multipartite systems [J]. Physical
	Review Letters, 2008, 101(8): 080503.
[8]	Yu T, Eberly J H. Finite-time disentanglement via spontaneous emission [J]. Physical Review Letters, 2004, 93(14): 140404.
[9]	Laine E M, Breuer H P, Piilo J. Nonlocal memory effects allow perfect teleportation with mixed states [J]. Scientific Reports,
20	12, 4(4): 4620.
[10]	Kamta G L, Starace A F. Anisotropy and magnetic field effects on the entanglement of a two qubit Heisenberg XY chain [J].
	Physical Review Letters, 2002, 88(10): 107901.
[11]	Sun Y, Chen Y G, Chen H. Thermal entanglement in the two-qubit Heisenberg XY model under a nonuniform external magnetic
	field [J]. Physical Review A, 2003, 68(4): 044301.
[12]	Yu T, Di´osi L, Gisin N, et al. Non-Markovian quantum-state diffusion: Perturbation approach [J]. Physical Review A, 1999,
60	(1): 91.
[13]	Diosi L, Gisin N, Strunz W T. Non-Markovian quantum state diffusion [J]. Physical Review A, 1998, 58(3): 1699-1712.
[14]	Zhao X Y, Jing J, Corn B, et al. Dynamics of interacting qubits coupled to a common bath: Non-Markovian quantum state
	diffusion approach [J]. Physical Review A, 2011, 84(3): 5200-5212.
[15]	Chen Y S, ShiWF, Zeng D B, et al. Measurement back action on qubit systems by a cavity probe [J]. Quantum Physics, 2018,
	arxiv: 1803.11294. [16] Jing J, Yu T, Lam C H, et al. Control relaxation via dephasing: An exact quantum state diffusion study [J]. Physical Review A,
20	17, 97: 012104.
[17]	Chiu T Y. Non-Markovian master equation for interacting qubits coupled to abosonic bath: Analytic form and asymptotic
	approximation [J]. Quantum Physics, 2015, 3(3): 1983-1989.
[18]	Zhang G F. Thermal entanglement and teleportation in a two-qubit Heisenberg chain with Dzyaloshinski-Moriya anisotropic
	antisymmetric interaction [J]. Physical Review A, 2007, 75(3): 723-727.
[19]	Qin Meng, Li Yanbiao, Bai Zhong, et al. Effects of different Dzyaloshinskii-Moriya interaction and magnetic held on entanglement
	and fidelity intrinsic decoherence in a spin system [J]. Acta Physica Sinica (物理学报), 2014, 63(11): 110302 (in
	Chinese).
[20]	Strunz W T. The Brownian motion stochastic Schr¨odinger equation [J]. Chemical Physics, 2001, 268(1): 237-248.
[21]	Su Xiaoqin, Guo Guangcan. Quantum communication and quantum computation [J]. Chinese Journal of Quantum Electronics
	(量子电子学报), 2004, 21(6): 4-16 (in Chinese).
[22]	Shu W C, Zhao X Y, Jing J, et al. Uhrig dynamical control of a three-level system via non-Markovian quantum state diffusion
[J]	Journal of Physics B: Atomic Molecular & Optical Physics, 2014, 46(17): 175504.
[23]	Bowen G, Bose S. Teleportation as a depolarizing quantum channel, relative entropy, and classical capacity [J]. Physical Review
	Letters, 2001, 87(26): 267901.
[24]	Paerhati Parouke, Abliz Ahmad, Wang Fei, et al. Quantum telportation in the double Jaynes-Cummings coupling model [J].
	Journal of Xingjiang Normal University (Natural Science Edition) 新疆师范大学学报(自然科学版), 2015, (34): 59-64 (in
	Chinese).

Effect of non-Markovian environment on quantum teleportation via a two-qubit Heisenberg XXZ spin chain

Knowledge

Abstract

Cite this article

share this article

References 24

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	CHEN Liying , HUANG Kun , WANG Qi , YAN Shinong . Design of an integrated vibration detection module based on diamond NV color centers [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 500-509.
[2]	BAI Hailong , BAI Jinhai , HU Dong , WANG Yu . Design and implementation of a compact microwave synthesizer for atomic interference gravimeter [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 510-518.
[3]	LI Songsong. Effects of three-body and four-body interactions on spin squeezing and quantum entanglement in Bose-Einstein condensates [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 519-527.
[4]	LI Yan , . Correlation properties of Bose⁃Fermi mixture with one⁃dimensional strong interaction [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 528-540.
[5]	WANG Sheng , FANG Xiaoming , LIN Yu , ZHANG Tianbing , FENG Bao , YU Yang , WANG Le . Four-intensity decoy-state phase-matching quantum key distribution [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 541-545.
[6]	SUN Yishi , SUN Yi . Parameter prediction of classical-quantum signals co-fiber transmission system based on BP neural network [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 546-559.
[7]	QI Zhiming , LIANG Wenyao . Influence of beam polarizations on holographic fabrication of compound photonic crystals [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 447-457.
[8]	HE Yefeng , , LI Lina ∗ , BAI Qian , CHEN Sihao , QIANG Yuwei . Quantum key distribution of detector’s dead time in heralded single photon source [J]. Chinese Journal of Quantum Electronics, 2023, 40(1): 112-119.
[9]	TAN Zhijie , YANG Hairui , , YU Hong , , HAN Shensheng , ∗. Progress on X-ray diffraction imaging via intensity correlation [J]. Chinese Journal of Quantum Electronics, 2022, 39(6): 851-862.
[10]	LIN Huizu , ∗ , LIU Weitao , ∗ , SUN Shuai , , DU Longkun , , CHANG Chen , , LI Yuegang , . Progress of algorithms used in ghost imaging [J]. Chinese Journal of Quantum Electronics, 2022, 39(6): 863-879.
[11]	WANG Xiaoyan, WANG Zhiyuan, CHEN Ziyang, PU Jixioing ∗. Detection of orbital angular momentum of multiple vortices from speckle via deep learning [J]. Chinese Journal of Quantum Electronics, 2022, 39(6): 955-961.
[12]	LI Nengfei , SUN Yusong , , HUANG Jian , ∗. Research on cosine encoded multiplexing high spatial resolution ghost imaging [J]. Chinese Journal of Quantum Electronics, 2022, 39(6): 973-982.
[13]	DAI Pan, PANG Zhiguang, LI Jian, WANG Qin ∗. Nonlinear Bell inequality based on entanglement sources [J]. Chinese Journal of Quantum Electronics, 2022, 39(5): 761-767.
[14]	ZHOU Xiantao, JIANG Yinghua ∗ , GUO Chenfei, ZHAO Ning, LIU Biao. Quantum secure direct communication protocol based on mixture of GHZ particles and single photon [J]. Chinese Journal of Quantum Electronics, 2022, 39(5): 768-775.
[15]	LI Tianxiu, SHI Lei ∗ , WANG Junhui, LI Jiahao. Prediction of atmospheric attenuation coeﬃcient of quantum signal based on deep learning [J]. Chinese Journal of Quantum Electronics, 2022, 39(5): 786-794.