First-principles predictions of electronic properties of GaAs1-x-yPyBix and GaAs1-x-yPyBix-based heterojunctions

Significant efficiency droop is a major concern for light-emitting diodes and laser diodes operating at high current density. Recent study has suggested that heavily Bi-alloyed GaAs can decrease the non-radiative Auger recombination and therefore alleviate the efficiency droop. Using density functio...

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Veröffentlicht in:	Applied physics letters 2016-09, Vol.109 (11)
Hauptverfasser:	Luo Guangfu, ghani Kamran, Kuech, Thomas F, Morgan, Dane
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied physics Atomic properties Augers Density functional theory Efficiency Electronic properties Electronic structure Energy gap First principles Heterojunctions Infrared lasers Infrared radiation Light emitting diodes Offsets Organic light emitting diodes Quaternary alloys Semiconductor lasers
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creator	Luo Guangfu ghani Kamran Kuech, Thomas F Morgan, Dane
description	Significant efficiency droop is a major concern for light-emitting diodes and laser diodes operating at high current density. Recent study has suggested that heavily Bi-alloyed GaAs can decrease the non-radiative Auger recombination and therefore alleviate the efficiency droop. Using density functional theory, we studied a newly fabricated quaternary alloy, GaAs1-x-yPyBix, which can host significant amounts of Bi, through calculations of its band gap, spin-orbit splitting, and band offsets with GaAs. We found that the band gap changes of GaAs1-x-yPyBix relative to GaAs are determined mainly by the local structural changes around P and Bi atoms rather than their electronic structure differences. To obtain alloy with lower Auger recombination than GaAs bulk, we identified the necessary constraints on the compositions of P and Bi. Finally, we demonstrated that GaAs/GaAs1-x-yPyBix heterojunctions with potentially low Auger recombination can exhibit small lattice mismatch and large enough band offsets for strong carrier confinement. This work shows that the electronic properties of GaAs1-x-yPyBix are potentially suitable for high-power infrared light-emitting diodes and laser diodes with improved efficiency.
doi_str_mv	10.1063/1.4962729
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Recent study has suggested that heavily Bi-alloyed GaAs can decrease the non-radiative Auger recombination and therefore alleviate the efficiency droop. Using density functional theory, we studied a newly fabricated quaternary alloy, GaAs1-x-yPyBix, which can host significant amounts of Bi, through calculations of its band gap, spin-orbit splitting, and band offsets with GaAs. We found that the band gap changes of GaAs1-x-yPyBix relative to GaAs are determined mainly by the local structural changes around P and Bi atoms rather than their electronic structure differences. To obtain alloy with lower Auger recombination than GaAs bulk, we identified the necessary constraints on the compositions of P and Bi. Finally, we demonstrated that GaAs/GaAs1-x-yPyBix heterojunctions with potentially low Auger recombination can exhibit small lattice mismatch and large enough band offsets for strong carrier confinement. 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subjects	Applied physics Atomic properties Augers Density functional theory Efficiency Electronic properties Electronic structure Energy gap First principles Heterojunctions Infrared lasers Infrared radiation Light emitting diodes Offsets Organic light emitting diodes Quaternary alloys Semiconductor lasers
title	First-principles predictions of electronic properties of GaAs1-x-yPyBix and GaAs1-x-yPyBix-based heterojunctions
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