111 research outputs found
Light polarization measurements in tests of macrorealism
According to the world view of macrorealism, the properties of a given system
exist prior to and independent of measurement, which is incompatible with
quantum mechanics. Leggett and Garg put forward a practical criterion capable
of identifying violations of macrorealism, and so far experiments performed on
microscopic and mesoscopic systems have always ruled out in favor of quantum
mechanics. However, a macrorealist can always assign the cause of such
violations to the perturbation that measurements effect on such small systems,
and hence a definitive test would require using non-invasive measurements,
preferably on macroscopic objects, where such measurements seem more plausible.
However, the generation of truly macroscopic quantum superposition states
capable of violating macrorealism remains a big challenge. In this work we
propose a setup that makes use of measurements on the polarization of light, a
property which has been extensively manipulated both in classical and quantum
contexts, hence establishing the perfect link between the microscopic and
macroscopic worlds. In particular, we use Leggett-Garg inequalities and the
criterion of no-signaling in time to study the macrorealistic character of
light polarization for different kinds of measurements, in particular with
different degrees of coarse-graining. Our proposal is non-invasive for coherent
input states by construction. We show for states with well defined photon
number in two orthogonal polarization modes, that there always exists a way of
making the measurement sufficiently coarse-grained so that a violation of
macrorealism becomes arbitrarily small, while sufficiently sharp measurements
can always lead to a significant violation.Comment: Comments, suggestions, and constructive criticism are welcom
Optical implementability of the two-dimensional Quantum Walk
We propose an optical cavity implementation of the two-dimensional coined
quantum walk on the line. The implementation makes use of only classical
resources, and is tunable in the sense that a large number of different unitary
transformations can be implemented by tuning some parameters of the device.Comment: 9 pages, 3 figure
Regularized linearization for quantum nonlinear optical cavities: Application to Degenerate Optical Parametric Oscillators
Nonlinear optical cavities are crucial both in classical and quantum optics;
in particular, nowadays optical parametric oscillators are one of the most
versatile and tunable sources of coherent light, as well as the sources of the
highest quality quantum-correlated light in the continuous variable regime.
Being nonlinear systems, they can be driven through critical points in which a
solution ceases to exist in favour of a new one, and it is close to these
points where quantum correlations are the strongest. The simplest description
of such systems consists in writing the quantum fields as the classical part
plus some quantum fluctuations, linearizing then the dynamical equations with
respect to the latter; however, such an approach breaks down close to critical
points, where it provides unphysical predictions such as infinite photon
numbers. On the other hand, techniques going beyond the simple linear
description become too complicated especially regarding the evaluation of
two-time correlators, which are of major importance to compute observables
outside the cavity. In this article we provide a regularized linear description
of nonlinear cavities, that is, a linearization procedure yielding physical
results, taking the degenerate optical parametric oscillator as the guiding
example. The method, which we call self-consistent linearization, is shown to
be equivalent to a general Gaussian ansatz for the state of the system, and we
compare its predictions with those obtained with available exact (or
quasi-exact) methods.Comment: Comments and suggestions are welcom
Solitons in a photonic nonlinear quantum walk: lessons from the continuum
We analyse a nonlinear QW model which can be experimentally implemented using
the components of the electric field on an optical nonlinear Kerr medium, which
translates into a rotation in the coin operator, with an angle which depends
(in a nonlinear fashion) on the state of the walker. This simple dependence
makes it easy to consider the space-time continuum limit of the evolution
equation, which takes the form of a nonlinear Dirac equation. The analysis of
this continuum limit allows us, under some approximations, to gain some insight
into the nature of soliton structures, which is illustrated by our numerical
calculations. These solitons are stable structures whose trajectories can be
modulated by choosing the appropriate initial conditions. We have also studied
the stability of solitons when they are subject to an additional phase that
simulates an external electric field, and also explored if they are formed in
higher dimensional spaces
Dissipative structures in optomechanical cavities
Motivated by the increasing interest in the properties of multimode
optomechanical devices, here we study a system in which a driven mode of a
large-area optical cavity is despersively coupled to a deformable mechanical
element. Two different models naturally appear in such scenario, for which we
predict the formation of periodic patterns, localized structures (cavity
solitons), and domain walls, among other complex nonlinear phenomena. Further,
we propose a realistic design based on intracavity membranes where our models
can be studied experimentally. Apart from its relevance to the field of
nonlinear optics, the results put forward here are a necessary step towards
understanding the quantum properties of optomechanical systems in the multimode
regime of both the optical and mechanical degrees of freedom.Comment: Updated version with a more general model and a specific
implementation proposal. Comments and (constructive) criticism are welcom
Non-critically squeezed light via spontaneous rotational symmetry breaking
We theoretically address squeezed light generation through the spontaneous
breaking of the rotational invariance occuring in a type I degenerate optical
parametric oscillator (DOPO) pumped above threshold. We show that a DOPO with
spherical mirrors, in which the signal and idler fields correspond to first
order Laguerre-Gauss modes, produces a perfectly squeezed vacuum with the shape
of a Hermite-Gauss mode, within the linearized theory. This occurs at any
pumping level above threshold, hence the phenomenon is non-critical.
Imperfections of the rotational symmetry, due e.g. to cavity anisotropy, are
shown to have a small impact, hence the result is not singular.Comment: 4 pages, 1 figure, replaced with resubmitted versio
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