693 research outputs found
Entanglement in atomic resonance fluorescence
The resonance fluorescence from regular atomic systems is shown to represent
a continuous source of non-Gaussian entangled radiation propagating in two
different directions. For a single atom entanglement occurs under the same
conditions as squeezing. For more atoms, the entanglement can be more robust
against dephasing than squeezing, hence providing a useful continuous source
for various applications of entangled radiation.Comment: 4 pages, 1 figur
Precision shooting: Sampling long transition pathways
The kinetics of collective rearrangements in solution, such as protein
folding and nanocrystal phase transitions, often involve free energy barriers
that are both long and rough. Applying methods of transition path sampling to
harvest simulated trajectories that exemplify such processes is typically made
difficult by a very low acceptance rate for newly generated trajectories. We
address this problem by introducing a new generation algorithm based on the
linear short-time behavior of small disturbances in phase space. Using this
``precision shooting'' technique, arbitrarily small disturbances can be
propagated in time, and any desired acceptance ratio of shooting moves can be
obtained. We demonstrate the method for a simple but computationally
problematic isomerization process in a dense liquid of soft spheres. We also
discuss its applicability to barrier crossing events involving metastable
intermediate states.Comment: 9 pages, 12 figures, submitted to J. Chem. Phy
Optimal Squeezing in Resonance Fluorescence via Atomic-State Purification
Squeezing of atomic resonance fluorescence is shown to be optimized by a
properly designed environment, which can be realized by a quasi-resonant
cavity. Optimal squeezing is achieved if the atomic coherence is maximized,
corresponding to a pure atomic quantum state. The atomic-state purification is
achieved by the backaction of the cavity field on the atom, which increases the
atomic coherence and decreases the atomic excitation. For realistic cavities,
the coupling of the atom to the cavity field yields a purity of the atomic
state of more than 99%. The fragility of squeezing against dephasing is
substantially reduced in this scenario, which may be important for various
applications.Comment: 6 pages including supplemental information, 3 figures. Accepted for
PR
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