Katherine J. Rae scite author profile

A key benefit of photonic crystal surface emitting lasers (PCSELs) is the abillity to increase output power through scaling the emission area while mainting high quality single mode emission, allowing them to close the brightness gap which exists between semiconductor lasers and gas and fibre lasers. However, there are practical limits to the size, and hence power, of an individual PCSEL device and there are trade-offs between single-mode stability and parasitic in-plane losses with increasing device size. In this paper we discuss 2D coherent arrays as an approach to area and coherent power scaling of PCSELs. We demonstrate in two and three element PCSEL arrays an increase in the differential efficiency of the system due to a reduction in in-plane loss.

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Void engineering in epitaxially regrown GaAs-based photonic crystal surface emitting lasers by grating profile design

McKenzie

King

Rae

et al. 2021

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We report the engineering of air voids embedded in GaAs-based photonic crystal surface-emitting lasers realized by metalorganic vapor-phase epitaxy regrowth. Two distinct void geometries are obtained by modifying the photonic crystal grating profile within the reactor prior to regrowth. The mechanism of void formation is inferred from scanning transmission electron microscopy analysis, with the evolution of the growth front illustrated though the use of an AlAs/GaAs superlattice structure. Competition between rapid lateral growth of the (100) surface and slow diffusion across higher index planes is exploited in order to increase the void volume, leading to an order of magnitude reduction in threshold current and an increase in output power through an increase in the associated grating coupling strength.

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InGaN µLEDs integrated onto colloidal quantum dot functionalized ultra-thin glass

Rae¹,

Foucher²,

Guilhabert³

et al. 2017

Opt. Express

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Red-, orange-, and green-emitting integrated optoelectronic sources are demonstrated by transfer printing blue InGaN µLEDs onto ultra-thin glass platforms functionally enhanced with II-VI colloidal quantum dots (CQDs). The forward optical power conversion efficiency of these heterogeneously integrated devices is, respectively, 9%, 15%, and 14% for a blue light absorption over 95%. The sources are demonstrated in an orthogonal frequency division multiplexed (OFDM) visible light communication link reaching respective data transmission rates of 46 Mbps, 44 Mbps and 61 Mbps.

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Katherine J. Rae

1.5 μm Epitaxially Regrown Photonic Crystal Surface Emitting Laser Diode

Transfer-printed micro-LED and polymer-based transceiver for visible light communications

Coherent power scaling in photonic crystal surface emitting laser arrays

Void engineering in epitaxially regrown GaAs-based photonic crystal surface emitting lasers by grating profile design

InGaN µLEDs integrated onto colloidal quantum dot functionalized ultra-thin glass

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