Strain-induced self-organized growth of nanostructures: From step bunching to ordering in quantum dot superlattices - Concepedia

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Strain-induced self-organized growth of nanostructures: From step bunching to ordering in quantum dot superlattices

21

Citations

16

References

2000

Year

J. Stangl, V. Holý, M. Pinczolits, G. Springholz, G. Bauer, I. Kegel, T. H. Metzger, Jing Zhu, Karl Brünner, G. Abstreiter,

Journal of Vacuum Science & Technology B Microelectronics and Nanometer Structures Processing Measurement and Phenomena

EngineeringStrain-induced Self-organized GrowthDot PositionsOptoelectronic DevicesSilicon On InsulatorSige/si MultilayerSemiconductor NanostructuresSemiconductorsQuantum MaterialsNanostructure SynthesisNanoscale ScienceNanomechanicsMaterials SciencePhysicsCrystalline DefectsNanotechnologySemiconductor MaterialLateral OrderingNanocrystalline MaterialQuantum Dot SuperlatticesNanomaterialsSelf-assemblyCondensed Matter PhysicsApplied PhysicsMultilayer Heterostructures

Abstract

We have investigated the lateral ordering of dot positions in a SiGe/Si multilayer and, for comparison, in a PbSe/PbEuTe dot superlattice using grazing incidence small-angle scattering. The two samples represent two different approaches to achieve an enhanced ordering of dot positions in semiconductor heterostructures: in the SiGe/Si sample, step bunching in the multilayer grown on a vicinal Si substrate was exploited to reduce the fluctuations in lateral dot distances. In the PbSe/PbEuTe sample the strong elastic anisotropy leads to the formation of a three-dimensional dot “lattice,” exhibiting a very narrow distribution of dot distances.

References

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