67 research outputs found
A waveguide atom beamsplitter for laser-cooled neutral atoms
A laser-cooled neutral-atom beam from a low-velocity intense source is split
into two beams while guided by a magnetic-field potential. We generate our
multimode-beamsplitter potential with two current-carrying wires on a glass
substrate combined with an external transverse bias field. The atoms bend
around several curves over a -cm distance. A maximum integrated flux of
is achieved with a current density of
in the 100- diameter
wires. The initial beam can be split into two beams with a 50/50 splitting
ratio
The nitrogen-vacancy center in diamond re-visited
Symmetry considerations are used in presenting a model of the electronic
structure and the associated dynamics of the nitrogen-vacancy center in
diamond. The model accounts for the occurrence of optically induced spin
polarization, for the change of emission level with spin polarization and for
new measurements of transient emission. The rate constants given are in
variance to those reported previously.Comment: 12 pages 10 figure
Designing large, high-efficiency, high-numerical-aperture, transmissive meta-lenses for visible light
A metasurface lens (meta-lens) bends light using nanostructures on a flat surface. Macroscopic meta-lenses (mm- to cm-scale diameter) have been quite difficult to simulate and optimize, due to the large area, the lack of periodicity, and the billions of adjustable parameters. We describe a method for designing a large-area meta-lens that allows not only prediction of the efficiency and far-field, but also optimization of the shape and position of each individual nanostructure, with a computational cost that is almost independent of the lens size. As examples, we design three large NA = 0.94 meta-lenses: One with 79% predicted efficiency for yellow light, one with dichroic properties, and one broadband lens. All have a minimum feature size of 100nm.Engineering and Applied Science
Low Energy Wave Packet Tunneling from a Parabolic Potential Well through a High Potential Barrier
The problem of wave packet tunneling from a parabolic potential well through
a barrier represented by a power potential is considered in the case when the
barrier height is much greater than the oscillator ground state energy, and the
difference between the average energy of the packet and the nearest oscillator
eigenvalue is sufficiently small. The universal Poisson distribution of the
partial tunneling rates from the oscillator energy levels is discovered. The
explicit expressions for the tunneling rates of different types of packets
(coherent, squeezed, even/odd, thermal, etc.) are given in terms of the
exponential and modified Bessel functions. The tunneling rates turn out very
sensitive to the energy distributions in the packets, and they may exceed
significantly the tunneling rate from the energy state with the same average
number of quanta.Comment: 14 pages, LaTex type, to appear in Physics Letters
On the Potential of Large Ring Lasers
We describe a new ring laser with area A = 833 m^2 and update performance
statistics for several such machines. Anandan & Chaio 1982 judged ring lasers
inferior to matter interferometers as possible detectors of gravitational
waves. However, we note that geophysically interesting results have been
obtained from large ring lasers and that there is still a lot of room for
improvements.Comment: accepted optics communication
Novel Ferromagnetic Atom Waveguide with in situ loading
Magneto-optic and magnetostatic trapping is realized near a surface using
current carrying coils wrapped around magnetizable cores. A cloud of 10^7
Cesium atoms is created with currents less than 50 mA. Ramping up the current
while maintaining optical dissipation leads to tightly confined atom clouds
with an aspect ratio of 1:1000. We study the 3D character of the magnetic
potential and characterize atom number and density as a function of the applied
current. The field gradient in the transverse dimension has been varied from <
10 G/cm to > 1 kG/cm. By loading and cooling atoms in-situ, we have eliminated
the problem of coupling from a MOT into a smaller phase space.Comment: 4 pages, 4 figure
Noise limits in matter-wave interferometry using degenerate quantum gases
We analyze the phase resolution limit of a Mach-Zehnder atom interferometer
whose input consists of degenerate quantum gases of either bosons or fermions.
For degenerate gases, the number of atoms within one de Broglie wavelength is
larger than unity, so that atom-atom interactions and quantum statistics are no
longer negligible. We show that for equal atom numbers, the phase resolution
achievable with fermions is noticeably better than for interacting bosons.Comment: 4 pages, 5 figure
Anisotropic interactions of a single spin and dark-spin spectroscopy in diamond
The nitrogen-vacancy (N-V) center in diamond is a promising atomic-scale
system for solid-state quantum information processing. Its spin-dependent
photoluminescence has enabled sensitive measurements on single N-V centers,
such as: electron spin resonance, Rabi oscillations, single-shot spin readout
and two-qubit operations with a nearby 13C nuclear spin. Furthermore, room
temperature spin coherence times as long as 58 microseconds have been reported
for N-V center ensembles. Here, we have developed an angle-resolved
magneto-photoluminescence microscopy apparatus to investigate the anisotropic
electron spin interactions of single N-V centers at room temperature. We
observe negative peaks in the photoluminescence as a function of both magnetic
field magnitude and angle that are explained by coherent spin precession and
anisotropic relaxation at spin level anti-crossings. In addition, precise field
alignment unmasks the resonant coupling to neighboring dark nitrogen spins that
are not otherwise detected by photoluminescence. The latter results demonstrate
a means of investigating small numbers of dark spins via a single bright spin
under ambient conditions.Comment: 13 pages, 4 figure
Quantum Theory in Accelerated Frames of Reference
The observational basis of quantum theory in accelerated systems is studied.
The extension of Lorentz invariance to accelerated systems via the hypothesis
of locality is discussed and the limitations of this hypothesis are pointed
out. The nonlocal theory of accelerated observers is briefly described.
Moreover, the main observational aspects of Dirac's equation in noninertial
frames of reference are presented. The Galilean invariance of nonrelativistic
quantum mechanics and the mass superselection rule are examined in the light of
the invariance of physical laws under inhomogeneous Lorentz transformations.Comment: 25 pages, no figures, contribution to Springer Lecture Notes in
Physics (Proc. SR 2005, Potsdam, Germany, February 13 - 18, 2005
Atom lasers: production, properties and prospects for precision inertial measurement
We review experimental progress on atom lasers out-coupled from Bose-Einstein
condensates, and consider the properties of such beams in the context of
precision inertial sensing. The atom laser is the matter-wave analog of the
optical laser. Both devices rely on Bose-enhanced scattering to produce a
macroscopically populated trapped mode that is output-coupled to produce an
intense beam. In both cases, the beams often display highly desirable
properties such as low divergence, high spectral flux and a simple spatial mode
that make them useful in practical applications, as well as the potential to
perform measurements at or below the quantum projection noise limit. Both
devices display similar second-order correlations that differ from thermal
sources. Because of these properties, atom lasers are a promising source for
application to precision inertial measurements.Comment: This is a review paper. It contains 40 pages, including references
and figure
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