Entanglement dynamics during decoherence

The evolution of the entanglement between oscillators that interact with the same environment displays highly non-trivial behavior in the long time regime. When the oscillators only interact through the environment, three dynamical phases were identified (Paz and Roncaglia in Phys Rev Lett 100:22040...

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Autores principales: Paz, J.P., Roncaglia, A.J.
Formato: JOUR
Materias:
Decoherence
Entanglement
Quantum Brownian Motion
Arbitrary temperature
Dynamical phasis
Entanglement dynamics
Master equations
Non-trivial
Quantum Brownian motions
Sudden deaths
Three phasis
Time regime
Brownian movement
Equations of motion
Phase diagrams
Quantum entanglement
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_15700755_v8_n6_p535_Paz
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_15700755_v8_n6_p535_Paz
record_format dspace
spelling todo:paper_15700755_v8_n6_p535_Paz2023-10-03T16:26:48Z Entanglement dynamics during decoherence Paz, J.P. Roncaglia, A.J. Decoherence Entanglement Quantum Brownian Motion Arbitrary temperature Decoherence Dynamical phasis Entanglement dynamics Master equations Non-trivial Quantum Brownian motions Sudden deaths Three phasis Time regime Brownian movement Equations of motion Phase diagrams Quantum entanglement The evolution of the entanglement between oscillators that interact with the same environment displays highly non-trivial behavior in the long time regime. When the oscillators only interact through the environment, three dynamical phases were identified (Paz and Roncaglia in Phys Rev Lett 100:220401, 2008) and a simple phase diagram characterizing them was presented. Here we generalize those results to the cases where the oscillators are directly coupled and we show how a degree of mixidness can affect the final entanglement. In both cases, entanglement dynamics is fully characterized by three phases (SD: sudden death, NSD: no-sudden death and SDR: sudden death and revivals) which cover a phase diagram that is a simple variant of the previously introduced one. We present results when the oscillators are coupled to the environment through their position and also for the case where the coupling is symmetric in position and momentum (as obtained in the RWA). As a bonus, in the last case we present a very simple derivation of an exact master equation valid for arbitrary temperatures of the environment. © 2009 Springer Science+Business Media, LLC. Fil:Paz, J.P. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Roncaglia, A.J. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_15700755_v8_n6_p535_Paz
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Decoherence
Entanglement
Quantum Brownian Motion
Arbitrary temperature
Decoherence
Dynamical phasis
Entanglement dynamics
Master equations
Non-trivial
Quantum Brownian motions
Sudden deaths
Three phasis
Time regime
Brownian movement
Equations of motion
Phase diagrams
Quantum entanglement
spellingShingle Decoherence
Entanglement
Quantum Brownian Motion
Arbitrary temperature
Decoherence
Dynamical phasis
Entanglement dynamics
Master equations
Non-trivial
Quantum Brownian motions
Sudden deaths
Three phasis
Time regime
Brownian movement
Equations of motion
Phase diagrams
Quantum entanglement
Paz, J.P.
Roncaglia, A.J.
Entanglement dynamics during decoherence
topic_facet Decoherence
Entanglement
Quantum Brownian Motion
Arbitrary temperature
Decoherence
Dynamical phasis
Entanglement dynamics
Master equations
Non-trivial
Quantum Brownian motions
Sudden deaths
Three phasis
Time regime
Brownian movement
Equations of motion
Phase diagrams
Quantum entanglement
description The evolution of the entanglement between oscillators that interact with the same environment displays highly non-trivial behavior in the long time regime. When the oscillators only interact through the environment, three dynamical phases were identified (Paz and Roncaglia in Phys Rev Lett 100:220401, 2008) and a simple phase diagram characterizing them was presented. Here we generalize those results to the cases where the oscillators are directly coupled and we show how a degree of mixidness can affect the final entanglement. In both cases, entanglement dynamics is fully characterized by three phases (SD: sudden death, NSD: no-sudden death and SDR: sudden death and revivals) which cover a phase diagram that is a simple variant of the previously introduced one. We present results when the oscillators are coupled to the environment through their position and also for the case where the coupling is symmetric in position and momentum (as obtained in the RWA). As a bonus, in the last case we present a very simple derivation of an exact master equation valid for arbitrary temperatures of the environment. © 2009 Springer Science+Business Media, LLC.
format JOUR
author Paz, J.P.
Roncaglia, A.J.
author_facet Paz, J.P.
Roncaglia, A.J.
author_sort Paz, J.P.
title Entanglement dynamics during decoherence
title_short Entanglement dynamics during decoherence
title_full Entanglement dynamics during decoherence
title_fullStr Entanglement dynamics during decoherence
title_full_unstemmed Entanglement dynamics during decoherence
title_sort entanglement dynamics during decoherence
url http://hdl.handle.net/20.500.12110/paper_15700755_v8_n6_p535_Paz
work_keys_str_mv AT pazjp entanglementdynamicsduringdecoherence
AT roncagliaaj entanglementdynamicsduringdecoherence
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