Bright quantum dot light sources using monolithic microlenses on gold back-reflectors

Abstract

We present the fabrication process of bright GaAs quantum dot (QD) photon sources by non-deterministic embedding into broadband monolithic Al0.15Ga0.85As microlens arrays on gold-coated substrates. Arrays of cylindrical photoresist templates, with diameters ranging from 2 μ m to 5 μ m, are thermally reflowed and subsequently transferred into the Al0.15Ga0.85As thin-film semiconductor heterostructure with embedded quantum dots through an optimized anisotropic and three-dimensional shape-preserving reactive ion etching process. This methodology facilitated the fabrication of large-scale (2 mm × 4 mm) and densely packed arrays of uniformly shaped microlenses ( 40 × 103 mm-1), with the brightest emissions from QDs embedded in microlenses exhibiting lateral diameters and heights of 2.7 μ m and 1.35 μ m, respectively. Finite-difference time-domain simulations of both idealized and fabricated lens shapes provide a comprehensive three-dimensional analysis of the device performance and optimization potentials such as anti-reflection coatings. It is found that free-space extraction (fiber-coupled) efficiencies of up to 62 \% (37 \%) are achievable for hemispherical QD-microlenses on gold-coated substrates. A statistical model for the fabrication yield of QD-microlenses is developed and experimentally corroborated by photoluminescence spectroscopy of fabricated microlens arrays. This analysis exhibited a free-space intensity enhancement by factors of up to × 200 in approximately 1 out of 200 microlenses, showing good agreement to the theoretical expectations. This scalable fabrication strategy underscores the potential of these compact, high-efficiency sources offering new prospects for applications of these devices in future large-scale quantum networks.

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