12,838 research outputs found
An integrated source of broadband quadrature squeezed light
An integrated silicon nitride resonator is proposed as an ultra-compact
source of bright single-mode quadrature squeezed light at 850 nm. Optical
properties of the device are investigated and tailored through numerical
simulations, with particular attention paid to loss associated with interfacing
the device. An asymmetric double layer stack waveguide geometry with inverse
vertical tapers is proposed for efficient and robust fibre-chip coupling,
yielding a simulated total loss of -0.75 dB/facet. We assess the feasibility of
the device through a full quantum noise analysis and derive the output
squeezing spectrum for intra-cavity pump self-phase modulation. Subject to
standard material loss and detection efficiencies, we find that the device
holds promises for generating substantial quantum noise squeezing over a
bandwidth exceeding 1 GHz. In the low-propagation loss regime, approximately -7
dB squeezing is predicted for a pump power of only 50 mW.Comment: 23 pages, 12 figure
Squeezing in Bose-Einstein condensates with large numbers of atoms
We examine the feasibility of creating and measuring large relative number squeezing in multicomponent trapped Bose-Einstein condensates. In the absence of multimode effects, this squeezing can be arbitrarily large for arbitrarily large condensates, but
Binary homodyne detection for observing quadrature squeezing in satellite links
Optical satellite links open up new prospects for realizing quantum physical experiments over unprecedented length scales. We analyze and affirm the feasibility of detecting quantum squeezing in an optical mode with homodyne detection of only one bit resolution, as is found in satellites already in orbit. We show experimentally that, in combination with a coherent displacement, a binary homodyne detector can still detect quantum squeezing efficiently even under high loss. The sample overhead in comparison to nondiscretized homodyne detection is merely a factor of 3.3.Optical satellite links open up new prospects for realizing quantum physical experiments over unprecedented length scales. We analyze and affirm the feasibility of detecting quantum squeezing in an optical mode with homodyne detection of only one bit resolution, as is found in satellites already in orbit. We show experimentally that, in combination with a coherent displacement, a binary homodyne detector can still detect quantum squeezing efficiently even under high loss. The sample overhead in comparison to nondiscretized homodyne detection is merely a factor of 3.3
Squeezing based on nondegenerate frequency doubling internal to a realistic laser
We investigate theoretically the quantum fluctuations of the fundamental
field in the output of a nondegenerate second harmonic generation process
occuring inside a laser cavity. Due to the nondegenerate character of the
nonlinear medium, a field orthogonal to the laser field is for some operating
conditions indepedent of the fluctuations produced by the laser medium. We show
that this fact may lead to perfect squeezing for a certain polarization mode of
the fundamental field. The experimental feasibility of the system is also
discussed.Comment: 6 pages, 5 figure
Generating arbitrary photon-number entangled states for continuous-variable quantum informatics
We propose two experimental schemes that can produce an arbitrary
photon-number entangled state (PNES) in a finite dimension. This class of
entangled states naturally includes non-Gaussian continuous-variable (CV)
states that may provide some practical advantages over the Gaussian
counterparts (two-mode squeezed states). We particularly compare the
entanglement characteristics of the Gaussian and the non-Gaussian states in
view of the degree of entanglement and the Einstein-Podolsky-Rosen correlation,
and further discuss their applications to the CV teleportation and the
nonlocality test. The experimental imperfection due to the on-off
photodetectors with nonideal efficiency is also considered in our analysis to
show the feasibility of our schemes within existing technologies.Comment: published version, 13 pages, 7 figure
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