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Effects of static noise on the dynamics of quantum correlations for a system of three qubits

Department of Physics, Mesoscopic and Multilayer Structure Laboratory, University of Dschang, P. O. Box: 67 Dschang, Republic of Cameroon

E-mail Address: kenfacklionel300@gmail.com

Corresponding author.

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Tchoffo Martin

Department of Physics, Mesoscopic and Multilayer Structure Laboratory, University of Dschang, P. O. Box: 67 Dschang, Republic of Cameroon

E-mail Address: mtchoffo2000@yahoo.fr

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Fouokeng Georges Collince

Department of Physics, Mesoscopic and Multilayer Structure Laboratory, University of Dschang, P. O. Box: 67 Dschang, Republic of Cameroon

Laboratoire de Génie des Matériaux, Pôle Recherche-Innovation-Entrepreneuriat (PRIE), Institut Universitaire de la Côte, BP 3001 Douala, Republic of Cameroon

E-mail Address: fouokenggc2012@yahoo.fr

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, and

Lukong Cornelius Fai

Department of Physics, Mesoscopic and Multilayer Structure Laboratory, University of Dschang, P. O. Box: 67 Dschang, Republic of Cameroon

E-mail Address: corneliusfai@yahoo.fr

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https://doi.org/10.1142/S0217979217500461Cited by:11 (Source: Crossref)

Abstract

Correlations in open quantum systems exhibit peculiar phenomena under the effect of various sources of noise. Here, we investigate the dynamics of entanglement and quantum discord (QD) for three noninteracting qubits coupled with a classical environmental static noise characterized by an external random field. Two initial entangled states of the system are examined, namely, the GHZ- and $W$ $W$ -type states. The system-environment interaction is here analyzed in three different configurations, namely, independent, mixed and common environments. We find that the dynamics of quantum correlations are strongly affected by the type of system-environment interaction and the purity of the initial entangled state. Indeed, depending on the type of interaction and the value of the purity of the initial state, peculiar phenomena such as sudden death, revivals and long-time survival of quantum correlations are observed. On the other hand, our results clearly show that quantum correlations initially present in the $W$ $W$ -type states are less robust than those of the GHZ-type states. Furthermore, we find that the long-time survival of entanglement can be detected by means of the suitable entanglement witnesses.

Keywords:

PACS: 03.65.Yz, 03.67.Mn, 05.40.-a

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