139 research outputs found
Quantum state transfer between field and atoms in Electromagnetically Induced Transparency
We show that a quasi-perfect quantum state transfer between an atomic
ensemble and fields in an optical cavity can be achieved in Electromagnetically
Induced Transparency (EIT). A squeezed vacuum field state can be mapped onto
the long-lived atomic spin associated to the ground state sublevels of the
Lambda-type atoms considered. The EIT on-resonance situation show interesting
similarities with the Raman off-resonant configuration. We then show how to
transfer the atomic squeezing back to the field exiting the cavity, thus
realizing a quantum memory-type operation.Comment: 8 pages, 4 figure
Squeezing and entangling nuclear spins in helium 3
We present a realistic model for transferring the squeezing or the
entanglement of optical field modes to the collective ground state nuclear spin
of He using metastability exchange collisions. We discuss in detail the
requirements for obtaining good quantum state transfer efficiency and study the
possibility to readout the nuclear spin state optically
Atomic quantum memory: cavity vs single pass schemes
This paper presents a quantum mechanical treatment for both atomic and field
fluctuations of an atomic ensemble interacting with propagating fields, either
in Electromagnetically Induced Transparency or in a Raman situation. The atomic
spin noise spectra and the outgoing field spectra are calculated in both
situations. For suitable parameters both EIT and Raman schemes efficiently
preserve the quantum state of the incident probe field in the transfer process
with the atoms, although a single pass scheme is shown to be intrinsically less
efficient than a cavity scheme
Teleportation of an atomic ensemble quantum state
We propose a protocol to achieve high fidelity quantum state teleportation of
a macroscopic atomic ensemble using a pair of quantum-correlated atomic
ensembles. We show how to prepare this pair of ensembles using quasiperfect
quantum state transfer processes between light and atoms. Our protocol relies
on optical joint measurements of the atomic ensemble states and magnetic
feedback reconstruction
Dynamics of a pulsed continuous variable quantum memory
We study the transfer dynamics of non-classical fluctuations of light to the
ground-state collective spin components of an atomic ensemble during a pulsed
quantum memory sequence, and evaluate the relevant physical quantities to be
measured in order to characterize such a quantum memory. We show in particular
that the fluctuations stored into the atoms are emitted in temporal modes which
are always different than those of the readout pulse, but which can
nevertheless be retrieved efficiently using a suitable temporal mode-matching
technique. We give a simple toy model - a cavity with variable transmission -
which accounts for the behavior of the atomic quantum memory.Comment: 6 pages, 5 figure
Non-invasive vibrational mode spectroscopy of ion Coulomb crystals through resonant collective coupling to an optical cavity field
We report on a novel non-invasive method to determine the normal mode
frequencies of ion Coulomb crystals in traps based on the resonance enhanced
collective coupling between the electronic states of the ions and an optical
cavity field at the single photon level. Excitations of the normal modes are
observed through a Doppler broadening of the resonance. An excellent agreement
with the predictions of a zero-temperature uniformly charged liquid plasma
model is found. The technique opens up for investigations of the heating and
damping of cold plasma modes, as well as the coupling between them.Comment: 4 pages, 4 figure
Entanglement storage in atomic ensembles
We propose to entangle macroscopic atomic ensembles in cavity using
EPR-correlated beams. We show how the field entanglement can be almost
perfectly mapped onto the long-lived atomic spins associated with the ground
states of the ensembles, and how it can be retrieved in the fields exiting the
cavities after a variable storage time. Such a continuous variable quantum
memory is of interest for manipulating entanglement in quantum networks
Continuous variable entanglement using cold atoms
We present experimental demonstration of quadrature and polarization
entanglement generated via the interaction between a coherent linearly
polarized field and cold atoms in a high finesse optical cavity. The non linear
atom-field interaction produces two squeezed modes with orthogonal
polarizations which are used to generate a pair of non separable beams, the
entanglement of which is demonstrated by checking the inseparability criterion
for continuous variables recently derived by Duan et al. [Phys. Rev. Lett. 84,
2722 (2000)] and calculating the entanglement of formation [Giedke et al.,
Phys. Rev. Lett. 91, 107901 (2003)]
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