Photoluminescence study of initial interdiffusion of SiGe/Si quantum wells grown by ultrahigh vacuum-chemical vapor deposition

From National Research Council Canada

DOI	Resolve DOI: https://doi.org/10.1063/1.117609
Author	Search for: Lafontaine, H.¹; Search for: Houghton, D. C.¹; Search for: Rowell, N. L.¹; Search for: Aers, G.C.¹
Affiliation	National Research Council of Canada. NRC Institute for Microstructural Sciences
Format	Text, Article
Subject	annealing; CVD; diffusion; germanium silicides; interface structure; photoluminescence; quantum wells; silicon; strains
Abstract	SiGe quantum wells were grown at 525 °C using a commercially available, ultrahigh vacuum–chemical vapor deposition system, in which the purity of the material and quality of interfaces have already been demonstrated. Changes in photoluminescence line energies are monitored and the extent of interdiffusion in the wells during annealing is calculated. A strong initial enhancement of the diffusivity is observed in as-grown material. Material annealed using a two-step process in which strain and Ge peak concentrations are unchanged after the first (low temperature) step, shows a much lower interdiffusion during the second step. It is argued that strain alone cannot explain the enhanced interdiffusion, which is, thus, attributed to grown-in, nonequilibrium point defects.
Publication date	1996-09
In	Applied Physics Letters 69, no. 10 (September 1996): 1444–1446.
Language	English
NRC number	NRC-INMS-1123
NPARC number	5763471
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Record identifier	b1a33b57-8703-455a-87c4-d4ee95652628
Record created	2009-03-29
Record modified	2020-03-20

Date modified:: 2024-07-17