Mechanisms of Self-Ordering of Quantum Nanostructures Grown on Nonplanar Surfaces
- 5 October 1998
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 81 (14), 2962-2965
- https://doi.org/10.1103/physrevlett.81.2962
Abstract
We present an analytic model that explains the self-ordering of quantum nanostructures grown on nonplanar surfaces. Self-limiting growth in these structures results from the interplay among growth-rate anisotropy, curvature-induced capillarity, and, for alloys, entropy of mixing effects. Experimental results on self-limiting organometallic chemical vapor deposition on corrugated surfaces are in quantitative agreement with the model. The implications of the self-limiting growth characteristics on the self-ordering of quantum wells, wires, and dots are discussed.Keywords
This publication has 19 references indexed in Scilit:
- Seeded self-assembled GaAs quantum dots grown in two-dimensional V grooves by selective metal–organic chemical-vapor depositionApplied Physics Letters, 1998
- Self-limiting growth of quantum dot heterostructures on nonplanar {111}B substratesApplied Physics Letters, 1997
- Growth of modulation-doped quantum wires on V-groove patterned substratesJournal of Crystal Growth, 1997
- Self-ordering mechanism of quantum wires grown on nonplanar substratesSolid-State Electronics, 1996
- Low-pressure organometallic chemical vapor deposition of quantum wires on V-grooved substratesApplied Physics Letters, 1995
- Vertically Self-Organized InAs Quantum Box Islands on GaAs(100)Physical Review Letters, 1995
- Flow rate modulation epitaxy of AlGaAs/GaAs quantum wires on nonplanar substrateApplied Physics Letters, 1995
- Spectroscopy of Quantum Levels in Charge-Tunable InGaAs Quantum DotsPhysical Review Letters, 1994
- Atmospheric and low pressure metalorganic vapor phase epitaxial growth of vertical quantum wells and quantum well wires on submicron gratingsJournal of Electronic Materials, 1994
- Quantum Semiconductor StructuresPhysics Today, 1992