Modelling x-ray scattering from quantum dots using Keating energy-minimised structures

Modelling x-ray scattering from quantum dots using Keating energy-minimised structures

In a traditional analysis of surface x-ray diffraction data, the surface unit cell can be defined by a small set of parameters, and fitting of experimental data is accomplished using well-established procedures. A quantum dot (QD), however, may contain as many as 20,000 atoms, so a different approac...

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Veröffentlicht in:The European physical journal. ST, Special topics Special topics, 2009-02, Vol.167 (1), p.47-52
Hauptverfasser: Rawle, J. L., Howes, P. B.
Format: Artikel
Sprache:eng
Schlagworte:
Atomic
Classical and Continuum Physics
Condensed Matter Physics
Condensed matter: structure, mechanical and thermal properties
Cross-disciplinary physics: materials science
rheology
Exact sciences and technology
Materials Science
Measurement Science and Instrumentation
Molecular
Nanoscale materials and structures: fabrication and characterization
Nanoscale materials: clusters, nanoparticles, nanotubes, and nanocrystals
Optical and Plasma Physics
Physics
Physics and Astronomy
Quantum dots
Regular Article
Structure of solids and liquids
crystallography
X-ray diffraction and scattering
X-ray scattering (including small-angle scattering)
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Beschreibung
Zusammenfassung:In a traditional analysis of surface x-ray diffraction data, the surface unit cell can be defined by a small set of parameters, and fitting of experimental data is accomplished using well-established procedures. A quantum dot (QD), however, may contain as many as 20,000 atoms, so a different approach to data analysis is required. A method for modelling a quantum dot and relaxing the structure by minimising the Keating energy is presented, and the simulation of x-ray scattering from such models is described. A method is then developed for simulating the alloying of InAs and GaAs inside the QDs using intermediate Keating parameters. This removes the need to relax and average multiple models with randomly distributed atoms, which would increase the computation time significantly.
ISSN:1951-6355
1951-6401
DOI:10.1140/epjst/e2009-00935-6