791 research outputs found
From a single- to a double-well Penning trap
The new generation of planar Penning traps promises to be a flexible and
versatile tool for quantum information studies. Here, we propose a fully
controllable and reversible way to change the typical trapping harmonic
potential into a double-well potential, in the axial direction. In this
configuration a trapped particle can perform coherent oscillations between the
two wells. The tunneling rate, which depends on the barrier height and width,
can be adjusted at will by varying the potential difference applied to the trap
electrodes. Most notably, tunneling rates in the range of kHz are achievable
even with a trap size of the order of 100 microns.Comment: 4 pages, 7 figure
Spin chains with electrons in Penning traps
We demonstrate that spin chains are experimentally feasible using electrons
confined in micro-Penning traps, supplemented with local magnetic field
gradients. The resulting Heisenberg-like system is characterized by coupling
strengths showing a dipolar decay. These spin chains can be used as a channel
for short distance quantum communication. Our scheme offers high accuracy in
reproducing an effective spin chain with relatively large transmission rate.Comment: 21 pages, 1 figure, accepted for publication in PR
Entangling two distant non-interacting microwave modes
We propose a protocol able to prepare two remote and initially uncorrelated
microwave modes in an entangled stationary state, which is certifiable using
only local optical homodyne measurements. The protocol is an extension of
continuous variable entanglement swapping, and exploits two hybrid
quadripartite opto-electro-mechanical systems in which a nanomechanical
resonator acts as a quantum interface able to entangle optical and microwave
fields. The proposed protocol allows to circumvent the problems associated with
the fragility of microwave photons with respect to thermal noise and may
represent a fundamental tool for the realization of quantum networks connecting
distant solid-state and superconducting qubits, which are typically manipulated
with microwave fields. The certifying measurements on the optical modes
guarantee the success of entanglement swapping without the need of performing
explicit measurements on the distant microwave fields.Comment: 7 pages, 3 figures; to appear in the special issue "Quantum and
Hybrid Mechanical Systems - From Fundamentals to Applications" in Annalen der
Physi
Radiation Pressure Induced Einstein-Podolsky-Rosen Paradox
We demonstrate the appearance of Einstein-Podolsky-Rosen (EPR) paradox when a
radiation field impinges on a movable mirror. The, the possibility of a local
realism test within a pendular Fabry-Perot cavity is shown to be feasible.Comment: 4 pages ReVTeX, 1 eps figur
Endoscopic Tomography and Quantum-Non-Demolition
We propose to measure the quantum state of a single mode of the radiation
field in a cavity---the signal field---by coupling it via a
quantum-non-demolition Hamiltonian to a meter field in a highly squeezed state.
We show that quantum state tomography on the meter field using balanced
homodyne detection provides full information about the signal state. We discuss
the influence of measurement of the meter on the signal field.Comment: RevTeX, 10 pages, 1 eps figure with psfig. To appear In Physical
Review A 59 (January 1999
A model independent approach to non dissipative decoherence
We consider the case when decoherence is due to the fluctuations of some
classical variable or parameter of a system and not to its entanglement with
the environment. Under few and quite general assumptions, we derive a
model-independent formalism for this non-dissipative decoherence, and we apply
it to explain the decoherence observed in some recent experiments in cavity QED
and on trapped ions.Comment: 12 pages, 3 figure
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