Journal ArticleDOI
Self-organization in growth of quantum dot superlattices.
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TLDR
The growth of multilayer arrays of coherently strained islands self-organizes into a more regular three-dimensional arrangement, providing a possible route to obtain the size uniformity needed for electronic applications of quantum dot arrays.Abstract:
We investigate the growth of multilayer arrays of coherently strained islands, which may serve as ``quantum dots'' in electronic devices. A simple model reproduces the observed vertical correlation between islands in successive layers. However, the arrangement of islands is not simply repeated from layer to layer. Instead, the island size and spacing grow progressively more uniform. In effect, the structure ``self-organizes'' into a more regular three-dimensional arrangement, providing a possible route to obtain the size uniformity needed for electronic applications of quantum dot arrays.read more
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Book ChapterDOI
Vertical correlation-anticorrelation transition in InAs/GaAs quantum dot structures grown by molecular beam epitaxy
TL;DR: In this paper, the first experimental evidence of anticorrelated InAs/GaAs quantum dot structures grown by molecular beam epitaxy was presented, showing that a transition occurs between correlated and anticor related vertical arrangements depending on the ratio between the layer separation and the average spacing between quantum dots in a single plane.
Proceedings ArticleDOI
Determination of coherent strain field in periodic and self-assembled microstructures on crystal surfaces
Qun Shen,Stefan Kycia +1 more
TL;DR: In this paper, high-resolution x-ray diffraction analyses on coherent thin-film microstructures on crystal surfaces can reveal a variety of information on interfacial strain fields, including diffuse interference fringes, asymmetric grating diffraction patterns, and asymmetric crystal-truncation-rod profiles.
Journal ArticleDOI
Reasons for self ordering in multilayer quantum dots Part II: Interaction energy
TL;DR: In this article, two ways to calculate the elastic interaction between quantum dots (QDs) in the framework of linear elasticity are introduced and shown to vary in a similar way as the hydrostatic pressure.