Modelling the effects of p-modulation doping in InAs/InGaAs quantum dot devices

被引:0
作者
Benjamin Maglio
Lydia Jarvis
Mingchu Tang
Huiyun Liu
Peter M. Smowton
机构
[1] Cardiff University,School of Physics & Astronomy
[2] University College London,Department of Electronic and Electrical Engineering
[3] UCL,undefined
来源
Optical and Quantum Electronics | / 56卷
关键词
p-modulation doping; Quantum dot lasers; Quantum confined Stark effect; Photonic integration;
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摘要
A modelling routine has been developed to quantify effects present in p-modulation doped 1.3 μm InAs/InGaAs quantum dot laser and modulator devices. Utilising experimentally verified parameters, calculated modal absorption is compared to measurements, prior to simulation of structures under reverse and forward bias. Observed broadening and a reduction of absorption in p-doped structures is attributed primarily to increased carrier scattering rates and can bring benefit when structures are configured as optical modulators with enhancements in the figure of merit. However, increased carrier scattering limits the maximum modal gain that can be achieved for lasers. The state filling caused by p-doping only marginally reduces absorption but assists laser operation with increased differential gain and gain magnitude at lower current densities.
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