Influence of noises on remote state preparation using GHZ state

Hua Qiu Liang; Jin Ming Liu

doi:10.1088/0253-6102/50/3/23

Influence of noises on remote state preparation using GHZ state

Hua Qiu Liang
, Jin Ming Liu^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Using a quantum channel consisting of a GHZ state exposed to noisy environment, we investigate how to remotely prepare an entangled state and a qubit state, respectively. By solving the master equation in the Lindblad form, the influence of the various types of noises on the GHZ state is first discussed. Then we use the fidelity to describe how close the remotely prepared state and the initial state are. Our results show that the fidelity is a function of the decoherence rates and the angles of the initial state. It is found that for each of the two RSP schemes, the influence of the noise acting simultaneously in x, y, and z directions on the average fidelity is the strongest while the influence of the noise acting in x or z direction on the average fidelity is relatively weaker.

Original language	English
Pages (from-to)	643-647
Number of pages	5
Journal	Communications in Theoretical Physics
Volume	50
Issue number	3
DOIs	https://doi.org/10.1088/0253-6102/50/3/23
State	Published - 15 Sep 2008
Externally published	Yes

Keywords

Fidelity
GHZ state
Noisy environment
Remote state preparation

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10.1088/0253-6102/50/3/23

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abstract = "Using a quantum channel consisting of a GHZ state exposed to noisy environment, we investigate how to remotely prepare an entangled state and a qubit state, respectively. By solving the master equation in the Lindblad form, the influence of the various types of noises on the GHZ state is first discussed. Then we use the fidelity to describe how close the remotely prepared state and the initial state are. Our results show that the fidelity is a function of the decoherence rates and the angles of the initial state. It is found that for each of the two RSP schemes, the influence of the noise acting simultaneously in x, y, and z directions on the average fidelity is the strongest while the influence of the noise acting in x or z direction on the average fidelity is relatively weaker.",

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T1 - Influence of noises on remote state preparation using GHZ state

AU - Liang, Hua Qiu

AU - Liu, Jin Ming

PY - 2008/9/15

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N2 - Using a quantum channel consisting of a GHZ state exposed to noisy environment, we investigate how to remotely prepare an entangled state and a qubit state, respectively. By solving the master equation in the Lindblad form, the influence of the various types of noises on the GHZ state is first discussed. Then we use the fidelity to describe how close the remotely prepared state and the initial state are. Our results show that the fidelity is a function of the decoherence rates and the angles of the initial state. It is found that for each of the two RSP schemes, the influence of the noise acting simultaneously in x, y, and z directions on the average fidelity is the strongest while the influence of the noise acting in x or z direction on the average fidelity is relatively weaker.

AB - Using a quantum channel consisting of a GHZ state exposed to noisy environment, we investigate how to remotely prepare an entangled state and a qubit state, respectively. By solving the master equation in the Lindblad form, the influence of the various types of noises on the GHZ state is first discussed. Then we use the fidelity to describe how close the remotely prepared state and the initial state are. Our results show that the fidelity is a function of the decoherence rates and the angles of the initial state. It is found that for each of the two RSP schemes, the influence of the noise acting simultaneously in x, y, and z directions on the average fidelity is the strongest while the influence of the noise acting in x or z direction on the average fidelity is relatively weaker.

KW - Fidelity

KW - GHZ state

KW - Noisy environment

KW - Remote state preparation

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DO - 10.1088/0253-6102/50/3/23

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VL - 50

SP - 643

EP - 647

JO - Communications in Theoretical Physics

JF - Communications in Theoretical Physics

IS - 3

ER -

Influence of noises on remote state preparation using GHZ state

Abstract

Keywords

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