152 research outputs found
A high frequency optical trap for atoms using Hermite-Gaussian beams
We present an experimental method to create a single high frequency optical
trap for atoms based on an elongated Hermite-Gaussian TEM01 mode beam. This
trap results in confinement strength similar to that which may be obtained in
an optical lattice. We discuss an optical setup to produce the trapping beam
and then detail a method to load a Bose-Einstein Condensate (BEC) into a TEM01
trap. Using this method, we have succeeded in producing individual highly
confined lower dimensional condensates.Comment: 9 pages, 5 figure
Hiding Single Photons With Spread Spectrum Technology
We describe a proof-of-principal experiment demonstrating the use of spread
spectrum technology at the single photon level. We show how single photons with
a prescribed temporal shape, in the presence of interfering noise, may be
hidden and recovered.Comment: 4 pages, 5 figures
Bose Einstein Condensate in a Box
Bose-Einstein condensates have been produced in an optical box trap. This
novel optical trap type has strong confinement in two directions comparable to
that which is possible in an optical lattice, yet produces individual
condensates rather than the thousands typical of a lattice. The box trap is
integrated with single atom detection capability, paving the way for studies of
quantum atom statistics.Comment: 4 pages, 5 figure
Direct Observation of Sub-Poissonian Number Statistics in a Degenerate Bose Gas
We report the direct observation of sub-Poissonian number fluctuation for a
degenerate Bose gas confined in an optical trap. Reduction of number
fluctuations below the Poissonian limit is observed for average numbers that
range from 300 to 60 atoms.Comment: 5 pages, 4 figure
Entanglement detection via condition of quantum correlation
We develop a novel necessary condition of quantum correlation. It is utilized
to construct -level bipartite Bell-type inequality which is strongly
resistant to noise and requires only analyses of measurement outcomes
compared to the previous result . Remarkably, a connection between
the arbitrary high-dimensional bipartite Bell-type inequality and entanglement
witnesses is found. Through the necessary condition of quantum correlation, we
propose that the witness operators to detect truly multipartite entanglement
for a generalized Greenberger-Horne-Zeilinger (GHZ) state with two local
measurement settings and a four-qubit singlet state with three settings.
Moreover, we also propose the first robust entanglement witness to detect
four-level tripartite GHZ state with only two local measurement settings
Spin dynamics with non-abelian Berry gauge fields as a semiclassical constrained hamiltonian system
The dynamics of observables which are matrices depending on \hbar and taking
values in classical phase space is defined retaining the terms up to the first
order in \hbar of the Moyal bracket. Within this semiclassical approach a first
order lagrangian involving gauge fields is studied as a constrained hamiltonian
system. This provides a systematic study of spin dynamics in the presence of
non-abelian Berry gauge fields. We applied the method to various types of
dynamical spin systems and clarified some persisting discussions. In particular
employing the Berry gauge field which generates the Thomas precession, we
calculated the force exerted on an electron in the external electric and
magnetic fields. Moreover, a simple semiclassical formulation of the spin Hall
effect is accomplished.Comment: References and some clarification added. Published versio
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