9,674 research outputs found
Broadband squeezed light from phase-locked single-mode sub-Poissonian lasers
We consider sub-Poissonian single-mode laser with external synchronization
and analyze its applicability to the problems of quantum information. Using
Heisenberg-Langevin theory we calculate the quadrature variances of the field
emitted by this laser. It is shown that such systems can demonstrate strong
quadrature squeezing. Taking into account that the emitted field is temporally
multi-mode the application of such sources to multichannel quantum
teleportation and dense coding protocols is discussed.Comment: 14 pages, 7 figure
Irreversibility on the Level of Single-Electron Tunneling
We present a low-temperature experimental test of the fluctuation theorem for
electron transport through a double quantum dot. The rare entropy-consuming
system trajectories are detected in the form of single charges flowing against
the source-drain bias by using time-resolved charge detection with a quantum
point contact. We find that these trajectories appear with a frequency that
agrees with the theoretical predictions even under strong nonequilibrium
conditions, when the finite bandwidth of the charge detection is taken into
account
Entanglement measurement of the quadrature components without the homodyne detection in the spatially multi-mode far-field
We consider the measuring procedure that in principle allows to avoid the
homodyne detection for the simultaneous selection of both quadrature components
in the far-field. The scheme is based on the use of the coherent sources of the
non-classical light. The possibilities of the procedure are illustrated on the
basis of the use of pixellised sources, where the phase-locked sub-Poissonian
lasers or the degenerate optical parametric oscillator generating above
threshold are chosen as the pixels. The theory of the pixellised source of the
spatio-temporal squeezed light is elaborated as a part of this investigation.Comment: 11 pages, 5 figures, RevTeX4. Submitted to Phys. Rev.
Nonequilibrium phenomena in multiple normal-superconducting tunnel heterostructures
Using the nonequilibrium theory of superconductivity with the tunnel
Hamiltonian, we consider a mesoscopic NISINISIN heterostructure, i.e., a
structure consisting of five intermittent normal-metal (N) and superconducting
(S) regions separated by insulating tunnel barriers (I). Applying the bias
voltage between the outer normal electrodes one can drive the central N island
very far from equilibrium. Depending on the resistance ratio of outer and inner
tunnel junctions, one can realize either effective electron cooling in the
central N island or create highly nonequilibrium energy distributions of
electrons in both S and N islands. These distributions exhibit multiple peaks
at a distance of integer multiples of the superconducting chemical potential.
In the latter case the superconducting gap in the S islands is strongly
suppressed as compared to its equilibrium value
- …