We describe the experimental progress and the challenges of integrating a single photon source based on quantum dots embedded in semiconductor nanowires with a cold-atom experiment in which laser-cooled caesium atoms are loaded and confined inside a hollow-core micro-structured optical fiber. We focus in particular on wavelength conversion of the photons between 895nm and wavelengths suitable for satellite links (~794nm).
We explore Fabry-Perot cavities formed by a pair of photonic-crystal slabs acting as mirrors as a platform for quantum optics at low light levels. We present our recent experimental demonstrations of polarization dichroic mirrors for both linearly and circularly polarized light and propose schemes in which cavities formed by such mirrors can be used to create single-photon optical nonlinearities in atomic ensembles.
We report loading of laser-cooled caesium atoms into a hollow-core photonic-bandgap fiber and confining the atoms in the fiber’s 7μm diameter core with a red-detuned dipole trap. In this system, the atom-photon interaction probability is in the range of 0.5% and optical depths exceeding 100 can be achieved. We discuss the outlooks for photon storage and nonlinear optics at low light levels, such as cross-phase modulation and single-photon wavelength conversion, in this system.
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