Title :
Self-organized anisotropic strain engineering: a new concept for quantum dot ordering
Author :
NÖtzel, Richard ; Mano, Takaaki ; Gong, Qian ; Wolter, Joachim H.
Author_Institution :
Eindhoven Univ. of Technol., Netherlands
fDate :
11/1/2003 12:00:00 AM
Abstract :
We have established a new concept for creating ordered arrays of quantum dots by self-organized epitaxy. The concept is based on self-organized anisotropic strain engineering of strained layer templates and is demonstrated for (In,Ga)As/GaAs superlattice structures on GaAs (100) and strain-induced (In,Ga)As growth instability on GaAs (311)B. The well-defined one- and two-dimensional networks of InAs quantum dots grown on top of these templates are of excellent structural and optical quality. This breakthrough, thus, allows for novel fundamental studies and device operation principles based on single and multiple carrier- and photon-, and coherent quantum interference effects.
Keywords :
III-V semiconductors; arrays; atomic force microscopy; gallium arsenide; indium compounds; internal stresses; molecular beam epitaxial growth; photoluminescence; quantum interference phenomena; semiconductor quantum dots; semiconductor superlattices; AFM images; GaAs; GaAs (100); GaAs (311)B; InAs; InGaAs-GaAs; InGaAs/GaAs superlattice structures; MBE; low-temperature PL spectra; one-dimensional networks; optical quality; ordered quantum dot arrays; quantum dot ordering; quantum interference effects; self-organized anisotropic strain engineering; self-organized epitaxy; strain-induced (In,Ga)As growth instability; strained layer templates; structural quality; two-dimensional networks; Anisotropic magnetoresistance; Capacitive sensors; Epitaxial growth; Gallium arsenide; Lithography; Molecular beam epitaxial growth; Optical arrays; Quantum dots; Substrates; US Department of Transportation;
Journal_Title :
Proceedings of the IEEE
DOI :
10.1109/JPROC.2003.818322
