2,234 research outputs found
Pure emitter dephasing : a resource for advanced solid-state single photon sources
We have computed the spectrum emitted spontaneously by a quantum dot coupled
to an arbitrarily detuned single mode cavity, taking into account pure
dephasing processes. We show that if the emitter is incoherent, the cavity can
efficiently emit photons with its own spectral characteristics. This effect
opens unique opportunities for the development of devices exploiting both
cavity quantum electrodynamics effects and pure dephasing, such as wavelength
stabilized single photon sources robust against spectral diffusion.Comment: 5 pages, 3 figure
Quantum Communication with Quantum Dot Spins
Single electron spins in quantum dots are attractive for quantum
communication because of their expected long coherence times. We propose a
method to create entanglement between two remote spins based on the coincident
detection of two photons emitted by the dots. Local nodes of several qubits can
be realized using the dipole-dipole interaction between trions in neighboring
dots and spectral addressing, allowing the realization of quantum repeater
protocols. We have performed a detailed feasibility study of our proposal based
on tight-binding calculations of quantum dot properties.Comment: 4 pages, 2 figures, new and improved version, explicit performance
estimate
Non-exponential spontaneous emission dynamics for emitters in a time-dependent optical cavity
We have theoretically studied the effect of deterministic temporal control of
spontaneous emission in a dynamic optical microcavity. We propose a new
paradigm in light emission: we envision an ensemble of two-level emitters in an
environment where the local density of optical states is modified on a time
scale shorter than the decay time. A rate equation model is developed for the
excited state population of two-level emitters in a time-dependent environment
in the weak coupling regime in quantum electrodynamics. As a realistic
experimental system, we consider emitters in a semiconductor microcavity that
is switched by free-carrier excitation. We demonstrate that a short temporal
increase of the radiative decay rate depletes the excited state and drastically
increases the emission intensity during the switch time. The resulting
time-dependent spontaneous emission shows a distribution of photon arrival
times that strongly deviates from the usual exponential decay: A deterministic
burst of photons is spontaneously emitted during the switch event.Comment: 12 pages, 4 figure
Optimal all-optical switching of a microcavity resonance in the telecom range using the electronic Kerr effect
We have switched GaAs/AlAs and AlGaAs/AlAs planar microcavities that operate
in the "Original" (O) telecom band by exploiting the instantaneous electronic
Kerr effect. We observe that the resonance frequency reversibly shifts within
one picosecond. We investigate experimentally and theoretically the role of
several main parameters: the material backbone and its electronic bandgap, the
pump power, the quality factor, and the duration of the switch pulse. The
magnitude of the shift is reduced when the backbone of the central
layer has a greater electronic bandgap; pumping with photon energies
near the bandgap resonantly enhances the switched magnitude. Our model shows
that the magnitude of the resonance frequency shift depends on the pump pulse
duration and is maximized when the duration matches the cavity storage time
that is set by the quality factor. We provide the settings for the essential
parameters so that the frequency shift of the cavity resonance can be increased
to one linewidth
Differential ultrafast all-optical switching of the resonances of a micropillar cavity
We perform frequency- and time-resolved all-optical switching of a GaAs-AlAs
micropillar cavity using an ultrafast pump-probe setup. The switching is
achieved by two-photon excitation of free carriers. We track the cavity
resonances in time with a high frequency resolution. The pillar modes exhibit
simultaneous frequency shifts, albeit with markedly different maximum switching
amplitudes and relaxation dynamics. These differences stem from the
non-uniformity of the free carrier density in the micropillar, and are well
understood by taking into account the spatial distribution of injected free
carriers, their spatial diffusion and surface recombination at micropillar
sidewalls.Comment: 4 pages, 3 figure
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