276 research outputs found
Manipulating mesoscopic multipartite entanglement with atom-light interfaces
Entanglement between two macroscopic atomic ensembles induced by measurement
on an ancillary light system has proven to be a powerful method for engineering
quantum memories and quantum state transfer. Here we investigate the
feasibility of such methods for generation, manipulation and detection of
genuine multipartite entanglement between mesoscopic atomic ensembles. Our
results extend in a non trivial way the EPR entanglement between two
macroscopic gas samples reported experimentally in [B. Julsgaard, A. Kozhekin,
and E. Polzik, Nature {\bf 413}, 400 (2001)]. We find that under realistic
conditions, a second orthogonal light pulse interacting with the atomic
samples, can modify and even reverse the entangling action of the first one
leaving the samples in a separable state.Comment: 8 pages, 6 figure
Distant Entanglement of Macroscopic Gas Samples
One of the main ingredients in most quantum information protocols is a
reliable source of two entangled systems. Such systems have been generated
experimentally several years ago for light but has only in the past few years
been demonstrated for atomic systems. None of these approaches however involve
two atomic systems situated in separate environments. This is necessary for the
creation of entanglement over arbitrary distances which is required for many
quantum information protocols such as atomic teleportation. We present an
experimental realization of such distant entanglement based on an adaptation of
the entanglement of macroscopic gas samples containing about 10^11 cesium atoms
shown previously by our group. The entanglement is generated via the
off-resonant Kerr interaction between the atomic samples and a pulse of light.
The achieved entanglement distance is 0.35m but can be scaled arbitrarily. The
feasibility of an implementation of various quantum information protocols using
macroscopic samples of atoms has therefore been greatly increased. We also
present a theoretical modeling in terms of canonical position and momentum
operators X and P describing the entanglement generation and verification in
presence of decoherence mechanisms.Comment: 20 pages book-style, 3 figure
Single-passage read-out of atomic quantum memory
A scheme for retrieving quantum information stored in collective atomic spin
systems onto optical pulses is presented. Two off-resonant light pulses cross
the atomic medium in two orthogonal directions and are interferometrically
recombined in such a way that one of the outputs carries most of the
information stored in the medium. In contrast to previous schemes our approach
requires neither multiple passes through the medium nor feedback on the light
after passing the sample which makes the scheme very efficient. The price for
that is some added noise which is however small enough for the method to beat
the classical limits.Comment: 8 pages, 2 figures, RevTeX
Non-Gaussian distribution of collective operators in quantum spin chains
We numerically analyse the behavior of the full distribution of collective
observables in quantum spin chains. While most of previous studies of quantum
critical phenomena are limited to the first moments, here we demonstrate how
quantum fluctuations at criticality lead to highly non-Gaussian distributions
thus violating the central limit theorem. Interestingly, we show that the
distributions for different system sizes collapse after scaling on the same
curve for a wide range of transitions: first and second order quantum
transitions and transitions of the Berezinskii-Kosterlitz-Thouless type. We
propose and carefully analyse the feasibility of an experimental reconstruction
of the distribution using light-matter interfaces for atoms in optical lattices
or in optical resonators.Comment: 15 pages, 5 figures; last version close to published versio
Characterization of Bose-Hubbard Models with Quantum Non-demolition Measurements
We propose a scheme for the detection of quantum phase transitions in the 1D
Bose-Hubbard (BH) and 1D Extended Bose-Hubbard (EBH) models, using the
non-demolition measurement technique of quantum polarization spectroscopy. We
use collective measurements of the effective total angular momentum of a
particular spatial mode to characterise the Mott insulator to superfluid phase
transition in the BH model, and the transition to a density wave state in the
EBH model. We extend the application of collective measurements to the ground
states at various deformations of a super-lattice potential.Comment: 8 pages, 9 figures; published version in PRA, Editors' Suggestio
Spin squeezing of atomic ensembles via nuclear-electronic spin entanglement
Entangled many body systems have recently attracted significant attention in
various contexts. Among them, spin squeezed atoms and ions have raised interest
in the field of precision measurements, as they allow to overcome quantum noise
of uncorrelated particles. Precise quantum state engineering is also required
as a resource for quantum computation, and spin squeezing can be used to create
multi-partite entangled states. Two-mode spin squeezed systems have been used
for elementary quantum communication protocols. Until now spin squeezing has
been always achieved via generation of entanglement between different atoms of
the ensemble. In this Letter, we demonstrate for the first time ensemble spin
squeezing generated by engineering the quantum state of each individual atom.
More specifically, we entangle the nuclear and electronic spins of
Cesium atoms at room temperature. We verify entanglement and ensemble spin
squeezing by performing quantum tomography on the atomic state.Comment: 5 pages, 3 figure
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