2,316 research outputs found
Nonlinear Temporal Dynamics of Strongly Coupled Quantum Dot-Cavity System
We theoretically analyze and simulate the temporal dynamics of strongly
coupled quantum dot-cavity system driven by a resonant laser pulse. We observe
the signature of Rabi oscillation in the time resolved response of the system
(i.e., in the numerically calculated cavity output), derive simplified linear
and non-linear semi-classical models that approximate well the system's
behavior in the limits of high and low power drive pulse, and describe the role
of quantum coherence in the exact dynamics of the system. Finally, we also
present experimental data showing the signature of the Rabi oscillation in time
domain
Theory of Pump Depletion and Spike Formation in Stimulated Raman Scattering
By using the inverse spectral transform, the SRS equations are solved and the
explicit output data is given for arbitrary laser pump and Stokes seed profiles
injected on a vacuum of optical phonons. For long duration laser pulses, this
solution is modified such as to take into account the damping rate of the
optical phonon wave. This model is used to interprete the experiments of Druhl,
Wenzel and Carlsten (Phys. Rev. Lett., (1983) vol. 51, p. 1171), in particular
the creation of a spike of (anomalous) pump radiation. The related nonlinear
Fourier spectrum does not contain discrete eigenvalue, hence this Raman spike
is not a soliton.Comment: LaTex file, includes two figures in LaTex format, 9 page
First-principles method for high- photonic crystal cavity mode calculations
We present a first-principles method to compute radiation properties of
ultra-high quality factor photonic crystal cavities. Our Frequency-domain
Approach for Radiation (FAR) can compute the far-field radiation pattern and
quality factor of cavity modes times more rapidly than conventional
finite-difference time domain calculations. It also provides a simple rule for
engineering the cavity's far-field radiation pattern
High-dimensional unitary transformations and boson sampling on temporal modes using dispersive optics
A major challenge for postclassical boson sampling experiments is the need for a large number of coupled optical modes, detectors, and single-photon sources. Here we show that these requirements can be greatly eased by time-bin encoding and dispersive optics-based unitary transformations. Detecting consecutively heralded photons after time-independent dispersion performs boson sampling from unitaries for which an efficient classical algorithm is lacking. We also show that time-dependent dispersion can implement general single-particle unitary operations. More generally, this scheme promises an efficient architecture for a range of other linear optics experiments.United States. Air Force Office of Scientific Research. Multidisciplinary University Research Initiative (Grant FA9550-14-1-0052
An integrated source of spectrally filtered correlated photons for large scale quantum photonic systems
We demonstrate the generation of quantum-correlated photon-pairs combined
with the spectral filtering of the pump field by more than 95dB using Bragg
reflectors and electrically tunable ring resonators. Moreover, we perform
demultiplexing and routing of signal and idler photons after transferring them
via a fiber to a second identical chip. Non-classical two-photon temporal
correlations with a coincidence-to-accidental ratio of 50 are measured without
further off-chip filtering. Our system, fabricated with high yield and
reproducibility in a CMOS process, paves the way toward truly large-scale
quantum photonic circuits by allowing sources and detectors of single photons
to be integrated on the same chip.Comment: 4 figure
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