Related papers: Probing multipartite entanglement, coherence and quantum information preservation under classical Ornstein-Uhlenbeck noise

Probing multipartite entanglement, coherence and quantum information preservation under classical Ornstein-Uhlenbeck noise

URL: http://arxiv.org/abs/2107.11251v1
Date: Fri, 23 Jul 2021 14:08:31 GMT
Title: Probing multipartite entanglement, coherence and quantum information preservation under classical Ornstein-Uhlenbeck noise
Authors: Atta Ur Rahman, Muhammad Javed, Arif Ullah,(Quantum Optics and Quantum Information Research Group, Department of Physics, University of Malakand), Khyber Pakhtunkhwa (Pakistan)
Abstract summary: We address entanglement, coherence, and information protection in a system of four non-interacting qubits coupled with classical environments. We show that quantum information preserved by the four qubit state is more dependent on the coherence than the entanglement.
Score: 0.4215938932388722
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We address entanglement, coherence, and information protection in a system of four non-interacting qubits coupled with different classical environments, namely: common, bipartite, tripartite, and independent environments described by Ornstein-Uhlenbeck (ORU) noise. We show that quantum information preserved by the four qubit state is more dependent on the coherence than the entanglement using time-dependent entanglement witness, purity, and Shannon entropy. We find these two quantum phenomena directly interrelated and highly vulnerable in environments with ORU noise, resulting in the pure exponential decay of a considerable amount. The current Markovian dynamical map, as well as suppression of the fluctuating character of the environments are observed to be entirely attributable to the Gaussian nature of the noise. Furthermore, the increasing number of environments are witnessed to accelerate the amount of decay. Unlike other noises, the current noise parameter's flexible range is readily exploitable, ensuring long enough preserved memory properties. The four-qubit GHZ state, besides having a large information storage potential, stands partially entangled and coherent in common environments for an indefinite duration. Thus, it appeared to be a more promising resource for functional quantum computing than bipartite and tripartite quantum systems. In addition, we derive computational values for each system-environment interaction, which will help quantum practitioners to optimize the related kind of classical environments.

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