426 research outputs found
Evaluation of the ultimate performances of a Ca+ single-ion frequency standard
We numerically evaluate the expected performances of an optical frequency
standard at 729 nm based on a single calcium ion. The frequency stability is
studied through the Allan deviation and its dependence on the excitation method
(single Rabi pulse or two Ramsey pulses schemes) and the laser linewidth are
discussed. The minimum Allan deviation that can be expected is estimated to
with the
integration time. The frequency shifts induced by the environmental conditions
are evaluated to minimize the uncertainty of the proposed standard by chosing
the most suited environment for the ion. If using the odd isotope
Ca and a vessel cooled to 77 K, the expected relative shift is with an uncertainty of , mainly due to
the quadrupole shift induced by the unknown static electric field gradient .Comment: soumis le 27/07/04 a Physics Letters
Searching for New Physics Through AMO Precision Measurements
We briefly review recent experiments in atomic, molecular, and optical
physics using precision measurements to search for physics beyond the Standard
Model. We consider three main categories of experiments: searches for changes
in fundamental constants, measurements of the anomalous magnetic moment of the
electron, and searches for an electric dipole moment of the electron.Comment: Prepared for Comments on AMO Physics at Physica Script
Phase locking a clock oscillator to a coherent atomic ensemble
The sensitivity of an atomic interferometer increases when the phase
evolution of its quantum superposition state is measured over a longer
interrogation interval. In practice, a limit is set by the measurement process,
which returns not the phase, but its projection in terms of population
difference on two energetic levels. The phase interval over which the relation
can be inverted is thus limited to the interval ; going beyond
it introduces an ambiguity in the read out, hence a sensitivity loss. Here, we
extend the unambiguous interval to probe the phase evolution of an atomic
ensemble using coherence preserving measurements and phase corrections, and
demonstrate the phase lock of the clock oscillator to an atomic superposition
state. We propose a protocol based on the phase lock to improve atomic clocks
under local oscillator noise, and foresee the application to other atomic
interferometers such as inertial sensors.Comment: 9 pages, 7 figure
Performance of a 229 Thorium solid-state nuclear clock
The 7.8 eV nuclear isomer transition in 229 Thorium has been suggested as an
etalon transition in a new type of optical frequency standard. Here we discuss
the construction of a "solid-state nuclear clock" from Thorium nuclei implanted
into single crystals transparent in the vacuum ultraviolet range. We
investigate crystal-induced line shifts and broadening effects for the specific
system of Calcium fluoride. At liquid Nitrogen temperatures, the clock
performance will be limited by decoherence due to magnetic coupling of the
Thorium nucleus to neighboring nuclear moments, ruling out the commonly used
Rabi or Ramsey interrogation schemes. We propose a clock stabilization based on
counting of flourescence photons and present optimized operation parameters.
Taking advantage of the high number of quantum oscillators under continuous
interrogation, a fractional instability level of 10^{-19} might be reached
within the solid-state approach.Comment: 28 pages, 9 figure
'Designer atoms' for quantum metrology
Entanglement is recognized as a key resource for quantum computation and
quantum cryptography. For quantum metrology, the use of entangled states has
been discussed and demonstrated as a means of improving the signal-to-noise
ratio. In addition, entangled states have been used in experiments for
efficient quantum state detection and for the measurement of scattering
lengths. In quantum information processing, manipulation of individual quantum
bits allows for the tailored design of specific states that are insensitive to
the detrimental influences of an environment. Such 'decoherence-free subspaces'
protect quantum information and yield significantly enhanced coherence times.
Here we use a decoherence-free subspace with specifically designed entangled
states to demonstrate precision spectroscopy of a pair of trapped Ca+ ions; we
obtain the electric quadrupole moment, which is of use for frequency standard
applications. We find that entangled states are not only useful for enhancing
the signal-to-noise ratio in frequency measurements - a suitably designed pair
of atoms also allows clock measurements in the presence of strong technical
noise. Our technique makes explicit use of non-locality as an entanglement
property and provides an approach for 'designed' quantum metrology
Hyperfine Spectroscopy of Optically Trapped Atoms
We perform spectroscopy on the hyperfine splitting of Rb atoms trapped
in far-off-resonance optical traps. The existence of a spatially dependent
shift in the energy levels is shown to induce an inherent dephasing effect,
which causes a broadening of the spectroscopic line and hence an inhomogeneous
loss of atomic coherence at a much faster rate than the homogeneous one caused
by spontaneous photon scattering. We present here a number of approaches for
reducing this inhomogeneous broadening, based on trap geometry, additional
laser fields, and novel microwave pulse sequences. We then show how hyperfine
spectroscopy can be used to study quantum dynamics of optically trapped atoms.Comment: Review/Tutoria
- âŠ