1,043 research outputs found
Detectability of dissipative motion in quantum vacuum via superradiance
We propose an experiment for generating and detecting vacuum-induced
dissipative motion. A high frequency mechanical resonator driven in resonance
is expected to dissipate energy in quantum vacuum via photon emission. The
photons are stored in a high quality electromagnetic cavity and detected
through their interaction with ultracold alkali-metal atoms prepared in an
inverted population of hyperfine states. Superradiant amplification of the
generated photons results in a detectable radio-frequency signal temporally
distinguishable from the expected background.Comment: 4 pages, 2 figure
Sympathetic cooling route to Bose-Einstein condensate and Fermi-liquid mixtures
We discuss a sympathetic cooling strategy that can successfully mitigate
fermion-hole heating in a dilute atomic Fermi-Bose mixture and access the
temperature regime in which the fermions behave as a Fermi liquid. We introduce
an energy-based formalism to describe the temperature dynamics with which we
study a specific and promising mixture composed of 6Li and 87Rb. Analyzing the
harmonically trapped mixture, we find that the favourable features of this
mixture are further enhanced by using different trapping frequencies for the
two species.Comment: 4 pages, 2 figure
Signatures of macroscopic quantum coherence in ultracold dilute Fermi gases
We propose a double-well configuration for optical trapping of ultracold
two-species Fermi-Bose atomic mixtures. Two signatures of macroscopic quantum
coherence attributable to a superfluid phase transition for the Fermi gas are
analyzed. The first signature is based upon tunneling of Fermi pairs when the
power of the deconfining laser beam is significantly reduced. The second relies
on the observation of interference fringes in a regime where the fermions are
trapped in two sharply separated minima of the potential. Both signatures rely
on small decoherence times for the Fermi samples, which should be possible by
reaching low temperatures using a Bose gas as a refrigerator, and a bichromatic
optical dipole trap for confinement, with optimal heat-capacity matching
between the two species
Uncertainty-principle noise in vacuum-tunneling transducers
The fundamental sources of noise in a vacuum-tunneling probe used as an
electromechanical transducer to monitor the location of a test mass are
examined using a first-quantization formalism. We show that a tunneling
transducer enforces the Heisenberg uncertainty principle for the position and
momentum of a test mass monitored by the transducer through the presence of two
sources of noise: the shot noise of the tunneling current and the momentum
fluctuations transferred by the tunneling electrons to the test mass. We
analyze a number of cases including symmetric and asymmetric rectangular
potential barriers and a barrier in which there is a constant electric field.
Practical configurations for reaching the quantum limit in measurements of the
position of macroscopic bodies with such a class of transducers are studied
Z2-graded cocharacters for superalgebras of triangular matrices
AbstractLet K be a field of characteristic zero, let A, B be K-algebras with polynomial identity and let M be a free (A,B)-bimodule. The algebra R=A0MB can be endowed with a natural Z2-grading. In this paper, we compute the graded cocharacter sequence, the graded codimension sequence and the superexponent of R. As a consequence of these results, we also study the above PI-invariants in the setting of upper triangular matrices. In particular, we completely classify the algebra of 3Ă—3 upper triangular matrices endowed with all possible Z2-gradings
Cooling dynamics of ultracold two-species Fermi-Bose mixtures
We compare strategies for evaporative and sympathetic cooling of two-species
Fermi-Bose mixtures in single-color and two-color optical dipole traps. We show
that in the latter case a large heat capacity of the bosonic species can be
maintained during the entire cooling process. This could allow to efficiently
achieve a deep Fermi degeneracy regime having at the same time a significant
thermal fraction for the Bose gas, crucial for a precise thermometry of the
mixture. Two possible signatures of a superfluid phase transition for the Fermi
species are discussed.Comment: 4 pages, 3 figure
A Step-by-step Guide to the Realisation of Advanced Optical Tweezers
Since the pioneering work of Arthur Ashkin, optical tweezers have become an
indispensable tool for contactless manipulation of micro- and nanoparticles.
Nowadays optical tweezers are employed in a myriad of applications
demonstrating the importance of these tools. While the basic principle of
optical tweezers is the use of a strongly focused laser beam to trap and
manipulate particles, ever more complex experimental set-ups are required in
order to perform novel and challenging experiments. With this article, we
provide a detailed step- by-step guide for the construction of advanced optical
manipulation systems. First, we explain how to build a single-beam optical
tweezers on a home-made microscope and how to calibrate it. Improving on this
design, we realize a holographic optical tweezers, which can manipulate
independently multiple particles and generate more sophisticated wavefronts
such as Laguerre-Gaussian beams. Finally, we explain how to implement a speckle
optical tweezers, which permit one to employ random speckle light fields for
deterministic optical manipulation.Comment: 29 pages, 7 figure
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