29 research outputs found
Hybrid quantum repeater based on resonant qubit-field interactions
We propose a hybrid quantum repeater based on ancillary coherent field states
and material qubits coupled to optical cavities. For this purpose, resonant
qubit-field interactions and postselective field measurements are determined
which are capable of realizing all necessary two-qubit operations for the
actuation of the quantum repeater. We explore both theoretical and experimental
possibilities of generating near-maximally-entangled qubit pairs ()
over long distances. It is shown that our scheme displays moderately low
repeater rates, between and pairs per second, over
distances up to km, and it relies completely on current technology of
cavity quantum electrodynamics.Comment: 18 pages, 13 figures, corrected according to published Erratu
Product formulas in the framework of mean ergodic theorems
An extension of Chernoff's product formula for one-parameter functions taking
values in the space of bounded linear operators on a Banach space is given.
Essentially, the -th one-parameter function in the product formula is mapped
by the -th iterate of a contraction acting on the space of the one-parameter
functions. The motivation to study this specific product formula lies in the
growing field of dynamical control of quantum systems, involving the procedure
of dynamical decoupling and also the Quantum Zeno effect.Comment: 10 page
Effects of stochastic noise on dynamical decoupling procedures
Dynamical decoupling is an important tool to counter decoherence and
dissipation effects in quantum systems originating from environmental
interactions. It has been used successfully in many experiments; however, there
is still a gap between fidelity improvements achieved in practice compared to
theoretical predictions. We propose a model for imperfect dynamical decoupling
based on a stochastic Ito differential equation which could explain the
observed gap. We discuss the impact of our model on the time evolution of
various quantum systems in finite- and infinite-dimensional Hilbert spaces.
Analytical results are given for the limit of continuous control, whereas we
present numerical simulations and upper bounds for the case of finite control.Comment: 15 pages, 6 figure
Positivity violations of the density operator in the Caldeira-Leggett master equation
The Caldeira-Leggett master equation as an example of Markovian master
equation without Lindblad form is investigated for mathematical consistency. We
explore situations both analytically and numerically where the positivity
violations of the density operator occur. We reinforce some known knowledge
about this problem but also find new surprising cases. Our analytical results
are based on the full solution of the Caldeira-Leggett master equation obtained
via the method of characteristics. The preservation of positivity is mainly
investigated with the help of the density operator's purity and we give also
some numerical results about the violation of the Robertson-Schr\"odinger
uncertainty relation.Comment: 13 pages, 12 figure
Dynamical control of quantum systems in the context of mean ergodic theorems
Equidistant and non-equidistant single pulse "bang-bang" dynamical controls
are investigated in the context of mean ergodic theorems. We show the
requirements in which the limit of infinite pulse control for both the
equidistant and the non-equidistant dynamical control converges to the same
unitary evolution. It is demonstrated that the generator of this evolution can
be obtained by projecting the generator of the free evolution onto the
commutant of the unitary operator representing the pulse. Inequalities are
derived to prove this statement and in the case of non-equidistant approach
these inequalities are optimised as a function of the time intervals.Comment: 25 page
Iterates of quantum operations
Iterates of quantum operations and their convergence are investigated in the
context of mean ergodic theory. We discuss in detail the convergence of the
iterates and show that the uniform ergodic theorem plays an essential role. Our
results will follow from some general theorems concerning completely positive
maps, mean ergodic operators, and operator algebras on Hilbert spaces. A few
examples of both finite and infinite dimensional Hilbert spaces are presented
as well.Comment: 14 page
An entropy production based method for determining the position diffusion's coefficient of a quantum Brownian motion
Quantum Brownian motion of a harmonic oscillator in the Markovian
approximation is described by the respective Caldeira-Leggett master equation.
This master equation can be brought into Lindblad form by adding a position
diffusion term to it. The coefficient of this term is either customarily taken
to be the lower bound dictated by the Dekker inequality or determined by more
detailed derivations on the linearly damped quantum harmonic oscillator. In
this paper, we explore the theoretical possibilities of determining the
position diffusion term's coefficient by analyzing the entropy production of
the master equation.Comment: 13 pages, 10 figure
Analytical evaluation of the coefficients of the Hu-Paz-Zhang master equation: Ohmic spectral density, zero temperature, and consistency check
We investigate the exact master equation of Hu, Paz, and Zhang for a quantum
harmonic oscillator at zero temperature with a Lorentz-Drude type Ohmic
spectral density. This master equation plays an important role in the study of
quantum Brownian motion and in various applications. In this paper, we give an
analytical evaluation of the coefficients of this non-Markovian master equation
without Lindblad form, which allows us to investigate consistencies of the
solutions, the positivity of the stationary density operator, and the
boundaries of the model's parameters.Comment: 17 pages, 8 figure
Entanglement in bipartite quantum systems: Euclidean volume ratios and detectability by Bell inequalities
Euclidean volume ratios between quantum states with positive partial
transpose and all quantum states in bipartite systems are investigated. These
ratios allow a quantitative exploration of the typicality of entanglement and
of its detectability by Bell inequalities. For this purpose a new numerical
approach is developed. It is based on the Peres-Horodecki criterion, on a
characterization of the convex set of quantum states by inequalities resulting
from Newton identities and from Descartes' rule of signs, and on a numerical
approach involving the multiphase Monte Carlo method and the hit-and-run
algorithm. This approach confirms not only recent analytical and numerical
results on two-qubit, qubit--qutrit, and qubit--four-level qudit states but
also allows for a numerically reliable numerical treatment of so far unexplored
qutrit--qutrit states. Based on this numerical approach with the help of the
Clauser-Horne-Shimony-Holt inequality and the Collins-Gisin inequality the
degree of detectability of entanglement is investigated for two-qubit quantum
states. It is investigated quantitatively to which extent a combined test of
both Bell inequalities can increase the detectability of entanglement beyond
what is achievable by each of these inequalities separately.Comment: 29 pages, 4 figure