The physical origin of InAs quantum dots on GaAs(001)
- 16 February 1998
- journal article
- research article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 72 (7), 783-785
- https://doi.org/10.1063/1.120892
Abstract
We propose that large heteroepitaxial stress causes InAs to melt when deposited on GaAs(001) at approximately 770 K. This leads to mixing with the substrate in order to realize a local minimum in the Gibbs free energy of the liquid phase, producing an approximate liquid composition of In 0.8 Ga 0.2 As . The liquid phase facilitates mass transport, leading to quantum dot formation. Dot formation occurs after 2.0 monolayers of liquid material accumulate in order to minimize the surface tension but without reducing the net coordination of the liquid phase atoms. Gequantum dots on Si(001) are also discussed, and the influence of viscosity effects is inferred.Keywords
This publication has 17 references indexed in Scilit:
- The Free Energy of Condensed Matter under StressJapanese Journal of Applied Physics, 1997
- 2D–3D transition in highly strained GaAsGa1 − xInxAs heterostructures by transmission electron microscopyJournal of Crystal Growth, 1997
- Ordered arrays of quantum dots: Formation, electronic spectra, relaxation phenomena, lasingSolid-State Electronics, 1996
- Growth and characterization of self-assembled Ge-rich islands on SiSemiconductor Science and Technology, 1996
- The strain energy density of cubic epitaxial layersJournal of Crystal Growth, 1996
- Dynamic effects of coherent epitaxial strain and surface stability: Ge on Si(100)Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures, 1992
- Activation energy for surface diffusion of Si on Si(001): A scanning-tunneling-microscopy studyPhysical Review Letters, 1991
- Unstable Region in Quaternary In1-xGaxAs1-ySby Calculated Using Strictly Regular Solution ApproximationJapanese Journal of Applied Physics, 1982
- Calculation of Miscibility Gap in Quaternary InGaPAs with Strictly Regular Solution ApproximationJapanese Journal of Applied Physics, 1982
- Melting and Polymorphism at High Pressures in Some Group IV Elements and III-V Compounds with the Diamond/Zincblende StructurePhysical Review B, 1963