Experiments Versus Modelling in Quantum Dot Pillar Microcavities

2006 International Conference on Transparent Optical Networks Pub Date : 2006-06-18 DOI:10.1109/ICTON.2006.248226

J. Rarity, Y. D. Ho, R. Gibson, C. Hu, M. Cryan, Ian J. Craddock, C. Railton, D. Sanvitto, A. Darei, M. Hopkinson, J. A. Timpson, A. M. Fox, M. S. Skolnick

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引用次数: 1

Abstract

Recently, single photon sources have been realised by coupling InAs quantum-dots into circular micro-pillar microcavities based on distributed Bragg reflectors (DBRs). These sources can be highly efficient because the high semiconductor refractive index collects a large fraction of the spontaneous emission into the waveguide mode. We have modelled emission from circular, square, elliptical and rectangular pillars using the finite difference time domain (FDTD) method and see enhanced emission into the cavity mode and improved efficiency for coupling light out of the microcavity. The cavity Q-factors can be very high even when the pillar diameter (dimension) is comparable to the emission wavelength. In the elliptical and rectangular cavities the modes separate (in frequency) into a high-Q resonance with polarisation parallel to the long axis and a lower Q-factor resonance with polarisation orthogonal to the long axis. We compare our modelling with preliminary measurements made on micro-pillar microcavity samples containing a layer of low density InAs dots at the cavity centre

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量子点柱微腔的实验与模拟

近年来，将InAs量子点耦合到基于分布式Bragg反射器(DBRs)的圆形微柱微腔中实现了单光子源。这些光源可以是高效率的，因为高半导体折射率收集自发发射到波导模式的很大一部分。我们利用时域有限差分(FDTD)方法对圆形、方形、椭圆形和矩形柱的发射进行了建模，发现微腔模式的发射增强了，耦合光的效率也提高了。当光柱直径(尺寸)与发射波长相当时，空腔q因子也会很高。在椭圆腔和矩形腔中，模式(在频率上)分为极化平行于长轴的高q共振和极化正交于长轴的低q因子共振。我们将我们的模型与微柱微腔样品的初步测量结果进行了比较，这些样品在腔中心含有一层低密度的InAs点

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2006 International Conference on Transparent Optical Networks

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