320 research outputs found
Climbing the Jaynes-Cummings ladder by photon counting
We present a new method to observe direct experimental evidence of
Jaynes--Cummings nonlinearities in a strongly dissipative cavity quantum
electrodynamics system, where large losses compete with the strong light-matter
interaction. This is a highly topical problem, particularly for quantum dots in
microcavities where transitions from higher rungs of the Jaynes--Cummings
ladder remain to be evidenced explicitly. We compare coherent and incoherent
excitations of the system and find that resonant excitation of the detuned
emitter make it possible to unambiguously evidence few photon quantum
nonlinearities in currently available experimental systems.Comment: 4 pages, 4 figures (color online). Updated bb
Towards on-chip generation, routing and detection of non-classical light
We fabricate an integrated photonic circuit with emitter, waveguide and
detector on one chip, based on a hybrid superconductor-semiconductor system. We
detect photoluminescence from self-assembled InGaAs quantum dots on-chip using
NbN superconducting nanowire single photon detectors. Using the fast temporal
response of these detectors we perform time-resolved studies of non-resonantly
excited quantum dots. By introducing a temporal filtering to the signal, we are
able to resonantly excite the quantum dot and detect its resonance uorescence
on-chip with the integrated superconducting single photon detector.Comment: 9 pages, 5 figure
Dynamic acousto-mechanical control of a strongly coupled photonic molecule
Two-dimensional photonic crystal membranes provide a versatile planar
architecture for integrated photonics to control the propagation of light on a
chip employing high quality optical cavities, waveguides, beamsplitters or
dispersive elements. When combined with highly non-linear quantum emitters,
quantum photonic networks operating at the single photon level come within
reach. Towards large-scale quantum photonic networks, selective dynamic control
of individual components and deterministic interactions between different
constituents are of paramount importance. This indeed calls for switching
speeds ultimately on the system's native timescales. For example, manipulation
via electric fields or all-optical means have been employed for switching in
nanophotonic circuits and cavity quantum electrodynamics studies. Here, we
demonstrate dynamic control of the coherent interaction between two coupled
photonic crystal nanocavities forming a photonic molecule. By using an
electrically generated radio frequency surface acoustic wave we achieve
optomechanical tuning, demonstrate operating speeds more than three orders of
magnitude faster than resonant mechanical approaches. Moreover, the tuning
range is large enough to compensate for the inherent fabrication-related cavity
mode detuning. Our findings open a route towards nanomechanically gated
protocols, which hitherto have inhibited the realization in all-optical
schemes.Comment: submitted manuscrip
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