Your search keyword '"Dalgarno, Paul"' showing total 3 results

1. A tunable microcavity.

Author

Barbour, Russell J., Dalgarno, Paul A., Curran, Arran, Nowak, Kris M., Baker, Howard J., Hall, Denis R., Stoltz, Nick G., Petroff, Pierre M., and Warburton, Richard J.

Subjects

*NANOTUBES, *QUANTUM dots, *SEMICONDUCTORS, *PHOTONS, *NANOCRYSTALS

Abstract

We present a generic microcavity platform for cavity experiments on optically active nanostructures, such as quantum dots, nanocrystals, color centers, and carbon nanotubes. The cavity is of the Fabry-Pérot type with a planar back mirror and a miniature concave top mirror with radius of curvature ∼ 100 μm. Optical access is achieved by free beam coupling, allowing good mode-matching to the cavity mode. The cavity has a high Q-factor, reasonably small mode volume, open access, spatial and spectral tunability, and operates at cryogenic temperatures. Spectral and spatial tuning of the Purcell effect (weak coupling regime) on a single InGaAs quantum dot is demonstrated. [ABSTRACT FROM AUTHOR]

Published

2011

2. Optical pumping of a single hole spin in a quantum dot.

Author

Gerardot, Brian D., Brunner, Daniel, Dalgarno, Paul A., Öhberg, Patrik, Seidl, Stefan, Kroner, Martin, Karrai, Khaled, Stoltz, Nick G., Petroff, Pierre M., and Warburton, Richard J.

Subjects

QUANTUM dots, ELECTRONS, ELECTRON spin echoes, ELECTRON paramagnetic resonance, MAGNETIC fields, QUANTUM electronics, PHOTONS, OPTICAL polarization, NANOTUBES

Abstract

The spin of an electron is a natural two-level system for realizing a quantum bit in the solid state. For an electron trapped in a semiconductor quantum dot, strong quantum confinement highly suppresses the detrimental effect of phonon-related spin relaxation. However, this advantage is offset by the hyperfine interaction between the electron spin and the 104 to 106 spins of the host nuclei in the quantum dot. Random fluctuations in the nuclear spin ensemble lead to fast spin decoherence in about ten nanoseconds. Spin-echo techniques have been used to mitigate the hyperfine interaction, but completely cancelling the effect is more attractive. In principle, polarizing all the nuclear spins can achieve this but is very difficult to realize in practice. Exploring materials with zero-spin nuclei is another option, and carbon nanotubes, graphene quantum dots and silicon have been proposed. An alternative is to use a semiconductor hole. Unlike an electron, a valence hole in a quantum dot has an atomic p orbital which conveniently goes to zero at the location of all the nuclei, massively suppressing the interaction with the nuclear spins. Furthermore, in a quantum dot with strong strain and strong quantization, the heavy hole with spin-3/2 behaves as a spin-1/2 system and spin decoherence mechanisms are weak. We demonstrate here high fidelity (about 99 per cent) initialization of a single hole spin confined to a self-assembled quantum dot by optical pumping. Our scheme works even at zero magnetic field, demonstrating a negligible hole spin hyperfine interaction. We determine a hole spin relaxation time at low field of about one millisecond. These results suggest a route to the realization of solid-state quantum networks that can intra-convert the spin state with the polarization of a photon. [ABSTRACT FROM AUTHOR]

Published

2008

3. Submicrometer photoresponse mapping of nanowire superconducting single-photon detectors.

Author

Hadfield, Robert H., Dalgarno, Paul A., O’Connor, John A., Ramsay, Euan, Warburton, Richard J., Gansen, Eric J., Baek, Burm, Stevens, Martin J., Mirin, Richard P., and Nam, Sae Woo

Subjects

*PHOTON detectors, *NANOWIRES, *PHOTONS, *SUPERCONDUCTORS, *CONFOCAL microscopy

Abstract

We report on the photoresponse mapping of nanowire superconducting single-photon detectors using a focal spot significantly smaller than the device area (10×10 μm2). Using a confocal microscope configuration and solid immersion lens, we achieve a spot size of 320 nm full width at half maximum onto the device at 470 nm wavelength. We compare the response maps of two devices: The higher detection efficiency device gives a uniform response, whereas the lower detection efficiency device is limited by a single defect or constriction. [ABSTRACT FROM AUTHOR]

Published

2007