263 research outputs found
Spin Hall mode in a trapped thermal Rashba gas
We theoretically investigate a two-dimensional harmonically-trapped gas of
identical atoms with Rashba spin-orbit coupling and no interatomic
interactions. In analogy with the spin Hall effect in uniform space, the gas
exhibits a spin Hall mode. In particular, in response to a displacement of the
center-of-mass of the system, spin-dipole moment oscillations occur. We
determine the properties of these oscillations exactly, and find that their
amplitude strongly depends on the spin-orbit coupling strength and the quantum
statistics of the particles
Optical vortices of slow light using tripod scheme
We consider propagation, storing and retrieval of slow light (probe beam) in
a resonant atomic medium illuminated by two control laser beams of larger
intensity. The probe and two control beams act on atoms in a tripod
configuration of the light-matter coupling. The first control beam is allowed
to have an orbital angular momentum (OAM). Application of the second
vortex-free control laser ensures the adiabatic (lossles) propagation of the
probe beam at the vortex core where the intensity of the first control laser
goes to zero. Storing and release of the probe beam is accomplished by
switching off and on the control laser beams leading to the transfer of the
optical vortex from the first control beam to the regenerated probe field. A
part of the stored probe beam remains frozen in the medium in the form of
atomic spin excitations, the number of which increases with increasing the
intensity of the second control laser. We analyse such losses in the
regenerated probe beam and provide conditions for the optical vortex of the
control beam to be transferred efficiently to the restored probe beam.Comment: 2 figure
Slow polaritons with orbital angular momentum in atomic gases
Polariton formalism is applied for studying the propagation of a probe field
of light in a cloud of cold atoms influenced by two control laser beams of
larger intensity. The laser beams couple resonantly three hyperfine atomic
ground states to a common excited state thus forming a tripod configuration of
the atomic energy levels involved. The first control beam can have an optical
vortex with the intensity of the beam going to zero at the vortex core. The
second control beam without a vortex ensures the loseless (adiabatic)
propagation of the probe beam at a vortex core of the first control laser. We
investigate the storage of the probe pulse into atomic coherences by switching
off the control beams, as well as its subsequent retrieval by switching the
control beams on. The optical vortex is transferred from the control to the
probe fields during the storage or retrieval of the probe field. We analyze
conditions for the vortex to be transferred efficiently to the regenerated
probe beam and discuss possibilities of experimental implementation of the
proposed scheme using atoms like rubidium or sodium.Comment: 4 figure
Communications carrier assembly, model A-3C Final report
Design and fabrication of personal communication system for spacecrew
Synthetic gauge fields in synthetic dimensions
We describe a simple technique for generating a cold-atom lattice pierced by
a uniform magnetic field. Our method is to extend a one-dimensional optical
lattice into the "dimension" provided by the internal atomic degrees of
freedom, yielding a synthetic 2D lattice. Suitable laser-coupling between these
internal states leads to a uniform magnetic flux within the 2D lattice. We show
that this setup reproduces the main features of magnetic lattice systems, such
as the fractal Hofstadter butterfly spectrum and the chiral edge states of the
associated Chern insulating phases.Comment: 5+4 pages, 5+3 figures, two-column revtex; v2: discussion of role of
interactions added, Fig. 1 reshaped, minor changes, references adde
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