The paper deals with silicon-based photonic crystal microcavities that are made light-emitting by means of local infiltration with semiconductor quantum dots. The microcavity structure is designed in order that the cavity mode is resonant with the emission wavelength of the dots. We report on the realization of a rewritable and local source inside a Si-based photonic crystal microcavity by infiltrating a solution of colloidal PbS quantum dots inside a single pore of the structure. We show that the resulting spontaneous emission from the source is both spatially and spectrally redistributed due to the mode structure of the photonic crystal cavity. The coupling of the quantum dot emission to the cavity mode is analyzed by mapping the luminescence signal of the infiltrated solution with a scanning near-field optical microscope at room temperature. Spectral characterization and the mode profile are in good agreement with a three-dimensional numerical calculation of the system. The paper results from a collaboration between the University of Pavia, the European Laboratory for Nonlinear Spectroscopy (LENS) in Firenze, and the Laboratoire de Photonique et de Nanostructures in Marcoussis (France) where the photonic crystal microcavities were fabricated.

Local nanofluidic light sources in silicon photonic crystal microcavities

BELOTTI, MICHELE;ANDREANI, LUCIO;
2008-01-01

Abstract

The paper deals with silicon-based photonic crystal microcavities that are made light-emitting by means of local infiltration with semiconductor quantum dots. The microcavity structure is designed in order that the cavity mode is resonant with the emission wavelength of the dots. We report on the realization of a rewritable and local source inside a Si-based photonic crystal microcavity by infiltrating a solution of colloidal PbS quantum dots inside a single pore of the structure. We show that the resulting spontaneous emission from the source is both spatially and spectrally redistributed due to the mode structure of the photonic crystal cavity. The coupling of the quantum dot emission to the cavity mode is analyzed by mapping the luminescence signal of the infiltrated solution with a scanning near-field optical microscope at room temperature. Spectral characterization and the mode profile are in good agreement with a three-dimensional numerical calculation of the system. The paper results from a collaboration between the University of Pavia, the European Laboratory for Nonlinear Spectroscopy (LENS) in Firenze, and the Laboratoire de Photonique et de Nanostructures in Marcoussis (France) where the photonic crystal microcavities were fabricated.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11571/137013
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