547 research outputs found
Phase-noise induced limitations on cooling and coherent evolution in opto-mechanical systems
We present a detailed theoretical discussion of the effects of ubiquitous
laser noise on cooling and the coherent dynamics in opto-mechanical systems.
Phase fluctuations of the driving laser induce modulations of the linearized
opto-mechanical coupling as well as a fluctuating force on the mirror due to
variations of the mean cavity intensity. We first evaluate the influence of
both effects on cavity cooling and find that for a small laser linewidth the
dominant heating mechanism arises from intensity fluctuations. The resulting
limit on the final occupation number scales linearly with the cavity intensity
both under weak and strong coupling conditions. For the strong coupling regime,
we also determine the effect of phase noise on the coherent transfer of single
excitations between the cavity and the mechanical resonator and obtain a
similar conclusion. Our results show that conditions for optical ground state
cooling and coherent operations are experimentally feasible and thus laser
phase noise does pose a challenge but not a stringent limitation for
opto-mechanical systems
Opto-mechanical transducers for long-distance quantum communication
We describe a new scheme to interconvert stationary and photonic qubits which
is based on indirect qubit-light interactions mediated by a mechanical
resonator. This approach does not rely on the specific optical response of the
qubit and thereby enables optical quantum interfaces for a wide range of solid
state spin and charge based systems. We discuss the implementation of quantum
state transfer protocols between distant nodes of a large scale network and
evaluate the effect of the main noise sources on the resulting state transfer
fidelities. For the specific examples of electronic spin qubits and
superconducting charge qubits we show that high fidelity quantum communication
protocols can be implemented under realistic experimental conditions.Comment: Version as accepted by PR
Single-photon Optomechanics
Optomechanics experiments are rapidly approaching the regime where the
radiation pressure of a single photon displaces the mechanical oscillator by
more than its zero-point uncertainty. We show that in this limit the power
spectrum has multiple sidebands and that the cavity response has several
resonances in the resolved-sideband limit. Using master-equation simulations,
we also study the crossover from the weak-coupling many-photon to the
single-photon strong-coupling regime. Finally, we find non-Gaussian
steady-states of the mechanical oscillator when multi-photon transitions are
resonant. Our study provides the tools to detect and take advantage of this
novel regime of optomechanics.Comment: 4 pages, 4 figure
Optomechanical quantum information processing with photons and phonons
We describe how strong resonant interactions in multimode optomechanical
systems can be used to induce controlled nonlinear couplings between single
photons and phonons. Combined with linear mapping schemes between photons and
phonons, these techniques provide a universal building block for various
classical and quantum information processing applications. Our approach is
especially suited for nano-optomechanical devices, where strong optomechanical
interactions on a single photon level are within experimental reach.Comment: 8 pages, 5 figure
Molecular Dipolar Crystals as High Fidelity Quantum Memory for Hybrid Quantum Computing
We study collective excitations of rotational and spin states of an ensemble
of polar molecules, which are prepared in a dipolar crystalline phase, as a
candidate for a high fidelity quantum memory. While dipolar crystals are formed
in the high density limit of cold clouds of polar molecules under 1D and 2D
trapping conditions, the crystalline structure protects the molecular qubits
from detrimental effects of short range collisions. We calculate the lifetime
of the quantum memory by identifying the dominant decoherence mechanisms, and
estimate their effects on gate operations, when a molecular ensemble qubit is
transferred to a superconducting strip line cavity (circuit QED). In the case
rotational excitations coupled by dipole-dipole interactions we identify
phonons as the main limitation of the life time of qubits. We study specific
setups and conditions, where the coupling to the phonon modes is minimized.
Detailed results are presented for a 1D dipolar chain
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Hybrid Quantum Devices and Quantum Engineering
We discuss prospects of building hybrid quantum devices involving elements of atomic and
molecular physics, quantum optics and solid-state elements with the attempt to combine
advantages of the respective systems in compatible experimental setups. In particular, we summarize our recent work on quantum hybrid devices and briefly discuss recent ideas for quantum networks. These include interfacing of molecular quantum memory with circuit QED, and using nanomechanical elements strongly coupled to qubits represented by electronic spins, as well as single atoms or atomic ensembles.Physic
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Phonon cooling and lasing with nitrogen-vacancy centers in diamond
We investigate the strain-induced coupling between a nitrogen-vacancy impurity and a resonant vibrational mode of a diamond nanoresonator. We show that under near-resonant laser excitation of the electronic states of the impurity, this coupling can modify the state of the resonator and either cool the resonator close to the vibrational ground state or drive it into a large-amplitude coherent state. We derive a semiclassical model to describe both effects and evaluate the stationary state of the resonator mode under various driving conditions. In particular, we find that by exploiting resonant single- and multiphonon transitions between near-degenerate electronic states, the coupling to high-frequency vibrational modes can be significantly enhanced and dominate over the intrinsic mechanical dissipation. Our results show that a single nitrogen-vacancy impurity can provide a versatile tool to manipulate and probe individual phonon modes in nanoscale diamond structures.Physic
Generation of Squeezed States of Nanomechanical Resonators by Reservoir Engineering
An experimental demonstration of a non-classical state of a nanomechanical
resonator is still an outstanding task. In this paper we show how the resonator
can be cooled and driven into a squeezed state by a bichromatic microwave
coupling to a charge qubit. The stationary oscillator state exhibits a reduced
noise in one of the quadrature components by a factor of 0.5 - 0.2. These
values are obtained for a 100 MHz resonator with a Q-value of 10 to 10
and for support temperatures of T 25 mK. We show that the coupling to
the charge qubit can also be used to detect the squeezed state via measurements
of the excited state population. Furthermore, by extending this measurement
procedure a complete quantum state tomography of the resonator state can be
performed. This provides a universal tool to detect a large variety of
different states and to prove the quantum nature of a nanomechanical
oscillator.Comment: 13 pages,9 figure
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