1,447 research outputs found
Open Quantum Dynamics: Complete Positivity and Entanglement
We review the standard treatment of open quantum systems in relation to
quantum entanglement, analyzing, in particular, the behaviour of bipartite
systems immersed in a same environment. We first focus upon the notion of
complete positivity, a physically motivated algebraic constraint on the quantum
dynamics, in relation to quantum entanglement, i.e. the existence of
statistical correlations which can not be accounted for by classical
probability. We then study the entanglement power of heat baths versus their
decohering properties, a topic of increasing importance in the framework of the
fast developing fields of quantum information, communication and computation.
The presentation is self contained and, through several examples, it offers a
detailed survey of the physics and of the most relevant and used techniques
relative to both quantum open system dynamics and quantum entanglement.Comment: LaTex, 77 page
Damped harmonic oscillators in the holomorphic representation
Quantum dynamical semigroups are applied to the study of the time evolution
of harmonic oscillators, both bosonic and fermionic. Explicit expressions for
the density matrices describing the states of these systems are derived using
the holomorphic representation. Bosonic and fermionic degrees of freedom are
then put together to form a supersymmetric oscillator; the conditions that
assure supersymmetry invariance of the corresponding dynamical equations are
explicitly derived.Comment: 19 pages, plain-TeX, no figure
Complete positivity and thermodynamics in a driven open quantum system
While it is well known that complete positivity guarantees the fulfilment of
the second law of thermodynamics, its possible violations have never been
proposed as a check of the complete positivity of a given open quantum
dynamics. We hereby consider an open quantum micro-circuit, effectively
describable as a two-level open quantum system, whose asymptotic current might
be experimentally accessible. This latter could indeed be used to discriminate
between its possible non-completely positive Redfield dynamics and a completely
positive one obtained by standard weak-coupling limit techniques, at the same
time verifying the fate of the second law of thermodynamics in such a context.Comment: 28 pages, 8 figures, LaTe
Dissipation and decoherence in photon interferometry
The propagation of polarized photons in optical media can be effectively
modeled by means of quantum dynamical semigroups. These generalized time
evolutions consistently describe phenomena leading to loss of phase coherence
and dissipation originating from the interaction with a large, external
environment. High sensitive experiments in the laboratory can provide stringent
bounds on the fundamental energy scale that characterizes these non-standard
effects.Comment: 14 pages, plain-Te
Planck's scale dissipative effects in atom interferometry
Atom interferometers can be used to study phenomena leading to
irreversibility and dissipation, induced by the dynamics of fundamental objects
(strings and branes) at a large mass scale. Using an effective, but physically
consistent description in terms of a master equation of Lindblad form, the
modifications of the interferometric pattern induced by the new phenomena are
analyzed in detail. We find that present experimental devices can in principle
provide stringent bounds on the new effects.Comment: 12 pages, plain-Te
Effective dissipative dynamics for polarized photons
In the framework of open quantum systems, the propagation of polarized
photons can be effectively described using quantum dynamical semigroups. These
extended time-evolutions induce irreversibility and dissipation. Planned, high
sensitive experiments, both in the laboratory and in space, will be able to put
stringent bounds on these non-standard effects.Comment: 15 pages, plain-TeX, no figure
Dissipative neutrino oscillations in randomly fluctuating matter
The generalized dynamics describing the propagation of neutrinos in randomly
fluctuating media is analyzed: it takes into account matter-induced,
decoherence phenomena that go beyond the standard MSW effect. A widely adopted
density fluctuation pattern is found to be physically untenable: a more general
model needs to be instead considered, leading to flavor changing effective
neutrino-matter interactions. They induce new, dissipative effects that modify
the neutrino oscillation pattern in a way amenable to a direct experimental
analysis.Comment: 14 pages, plain-Te
On tests of local realism by CP-violation parameters of K^0 mesons
Recently various papers have proposed to test local realism (LR) by
considering electroweak CP-violation parameters values in neutral pseudoscalar
meson systems. Considering the large interest for a conclusive test of LR and
the experimental accessibility to these tests, in this paper we critically
consider these results showing how they, albeit very interesting, require
anyway additional assumptions and therefore cannot be considered conclusive
tests of LR
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