Steepest-entropy-ascent quantum thermodynamic modeling of decoherence in two different microscopic composite systems
Articolo
Data di Pubblicazione:
2015
Abstract:
The steepest-entropy-ascent quantum thermodynamic (SEAQT) framework is used to model the decoherence
that occurs during the state evolution of two different microscopic composite systems. The test cases are a
two-spin-1/2-particle composite system and a particle-photon field composite system like that experimentally
studied in cavity quantum electrodynamics. The first system is used to study the characteristics of the nonlinear
equation of motion of the SEAQT framework when modeling the state evolution of a microscopic composite
system with particular interest in the phenomenon of decoherence. The second system is used to compare the
numerical predictions of the SEAQT framework with experimental cavity quantum electrodynamic data available
in the literature. For the two different numerical cases presented, the time evolution of the density operator of
the composite system as well as that of the reduced operators belonging to the two constituents is traced from
an initial nonequilibrium state of the composite along its relaxation towards stable equilibrium. Results show for
both cases how the initial entanglement and coherence is dissipated during the state relaxation towards a state of
stable equilibrium.
that occurs during the state evolution of two different microscopic composite systems. The test cases are a
two-spin-1/2-particle composite system and a particle-photon field composite system like that experimentally
studied in cavity quantum electrodynamics. The first system is used to study the characteristics of the nonlinear
equation of motion of the SEAQT framework when modeling the state evolution of a microscopic composite
system with particular interest in the phenomenon of decoherence. The second system is used to compare the
numerical predictions of the SEAQT framework with experimental cavity quantum electrodynamic data available
in the literature. For the two different numerical cases presented, the time evolution of the density operator of
the composite system as well as that of the reduced operators belonging to the two constituents is traced from
an initial nonequilibrium state of the composite along its relaxation towards stable equilibrium. Results show for
both cases how the initial entanglement and coherence is dissipated during the state relaxation towards a state of
stable equilibrium.
Tipologia CRIS:
1.1 Articolo in rivista
Keywords:
steepest entropy ascent, decoherence, quantum thermodynamics, nonlinear master equation
Elenco autori:
Cano Andrade, Sergio; Beretta, Gian Paolo; von Spakovsky, Michael
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