Domains of molecular beam epitaxial growth of Ga(In)AsBi on GaAs and InP substrates

We investigate the molecular beam epitaxial growth of GaAsBi and GaInAsBi layers on GaAs and InP-substrates as the materials are intended to serve as an active region in optoelectronic devices. The layers were grown at substrate temperatures between 250–400°C and for all layers the growth rate was k...

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Veröffentlicht in:	Journal of crystal growth 2016-02, Vol.436, p.56-61
Hauptverfasser:	Bennarndt, Wolfgang, Boehm, Gerhard, Amann, Markus-Christian
Format:	Artikel
Sprache:	eng
Schlagworte:	A3. Molecular beam epitaxy Arsenic B1. Alloys B1. Bismuth compounds B2. Semiconducting III–V materials Bismuth Crystal growth Flux Gallium arsenide Molecular beam epitaxy Overpressure Substrates
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container_title	Journal of crystal growth
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creator	Bennarndt, Wolfgang Boehm, Gerhard Amann, Markus-Christian
description	We investigate the molecular beam epitaxial growth of GaAsBi and GaInAsBi layers on GaAs and InP-substrates as the materials are intended to serve as an active region in optoelectronic devices. The layers were grown at substrate temperatures between 250–400°C and for all layers the growth rate was kept at a value of 1ML/s. We show that bismuth incorporation into Ga(In)As is independent of the applied arsenic (As4) overpressure and can be allocated to different growth domains depending solely on the parameters bismuth flux and substrate temperature, respectively. The maximum bismuth content that could be incorporated was as high as 20.0% in GaAs. •Bismuth containing III–V semiconductor alloys are promising for optoelectronic applications.•The challenges of bismide growth are the formation of defects and spinoidal decomposition.•Growth of bismides can be allocated to a variety of growth domains.
doi_str_mv	10.1016/j.jcrysgro.2015.11.021
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subjects	A3. Molecular beam epitaxy Arsenic B1. Alloys B1. Bismuth compounds B2. Semiconducting III–V materials Bismuth Crystal growth Flux Gallium arsenide Molecular beam epitaxy Overpressure Substrates
title	Domains of molecular beam epitaxial growth of Ga(In)AsBi on GaAs and InP substrates
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