Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 Algorithm

Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 Algorithm

The power of one qubit deterministic quantum processor (DQC1) (Knill and Laflamme (1998)) generates a nonclassical correlation known as quantum discord. The DQC1 algorithm executes in an efficient way with a characteristic time given by τ=Tr[Un]/2n, where Un is an n qubit unitary gate. For pure st...

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Main Authors: M. Ávila, G. H. Sun, A. L. Salas-Brito
Format: Article
Language:English
Published: Hindawi Limited 2014-01-01
Series:Advances in Mathematical Physics
Online Access:http://dx.doi.org/10.1155/2014/367905
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spelling doaj-0f4d348775ee4ea8beb783b055841d9a2021-07-02T03:15:42ZengHindawi LimitedAdvances in Mathematical Physics1687-91201687-91392014-01-01201410.1155/2014/367905367905Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 AlgorithmM. Ávila0G. H. Sun1A. L. Salas-Brito2Centro Universitario UAEM Valle de Chalco, UAEMex María Isabel, 56615 Valle de Chalco, MEX, MexicoCentro Universitario UAEM Valle de Chalco, UAEMex María Isabel, 56615 Valle de Chalco, MEX, MexicoInstituto de Ciencias Nucleares, Universidad Nacional Autónoma de México, Circuito Exterior, CU, Coyoacán, DF, MexicoThe power of one qubit deterministic quantum processor (DQC1) (Knill and Laflamme (1998)) generates a nonclassical correlation known as quantum discord. The DQC1 algorithm executes in an efficient way with a characteristic time given by τ=Tr[Un]/2n, where Un is an n qubit unitary gate. For pure states, quantum discord means entanglement while for mixed states such a quantity is more than entanglement. Quantum discord can be thought of as the mutual information between two systems. Within the quantum discord approach the role of time in an efficient evaluation of τ is discussed. It is found that the smaller the value of t/T is, where t is the time of execution of the DQC1 algorithm and T is the scale of time where the nonclassical correlations prevail, the more efficient the calculation of τ is. A Mösbauer nucleus might be a good processor of the DQC1 algorithm while a nuclear spin chain would not be efficient for the calculation of τ.http://dx.doi.org/10.1155/2014/367905
collection DOAJ
language English
format Article
sources DOAJ
author M. Ávila
G. H. Sun
A. L. Salas-Brito
spellingShingle M. Ávila
G. H. Sun
A. L. Salas-Brito
Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 Algorithm
Advances in Mathematical Physics
author_facet M. Ávila
G. H. Sun
A. L. Salas-Brito
author_sort M. Ávila
title Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 Algorithm
title_short Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 Algorithm
title_full Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 Algorithm
title_fullStr Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 Algorithm
title_full_unstemmed Scales of Time Where the Quantum Discord Allows an Efficient Execution of the DQC1 Algorithm
title_sort scales of time where the quantum discord allows an efficient execution of the dqc1 algorithm
publisher Hindawi Limited
series Advances in Mathematical Physics
issn 1687-9120
1687-9139
publishDate 2014-01-01
description The power of one qubit deterministic quantum processor (DQC1) (Knill and Laflamme (1998)) generates a nonclassical correlation known as quantum discord. The DQC1 algorithm executes in an efficient way with a characteristic time given by τ=Tr[Un]/2n, where Un is an n qubit unitary gate. For pure states, quantum discord means entanglement while for mixed states such a quantity is more than entanglement. Quantum discord can be thought of as the mutual information between two systems. Within the quantum discord approach the role of time in an efficient evaluation of τ is discussed. It is found that the smaller the value of t/T is, where t is the time of execution of the DQC1 algorithm and T is the scale of time where the nonclassical correlations prevail, the more efficient the calculation of τ is. A Mösbauer nucleus might be a good processor of the DQC1 algorithm while a nuclear spin chain would not be efficient for the calculation of τ.
url http://dx.doi.org/10.1155/2014/367905
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AT alsalasbrito scalesoftimewherethequantumdiscordallowsanefficientexecutionofthedqc1algorithm
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