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Relaxation of semiconductor nanostructures using molecular dynamics with analytic bond order potentials*

  • Kurt Scheerschmidt and Volker Kuhlmann
Published/Copyright: May 23, 2013
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International Journal of Materials Research
From the journal International Journal of Materials Research Volume 98 Issue 11

Abstract

Molecular dynamics simulations using empirical potentials have been performed to describe atomic interactions during the relaxation of nanostructures. To include the quantum mechanical nature of atomic bonding a tight-binding based bond order potential is developed applying analytically the first six moments. The bond order potential is improved using new on-site and -terms of the local density of states. The applicability of the bond order potential and resulting enhancements in structural predictions are analyzed recalculating quantum dot relaxations and interface defects arising during bonding of two wafers with twist rotation misalignment. The most important property proposed by the extended bond order potential is an increased stiffness of the bonds which give modifications of local atomic arrangements near defects.

Keywords: Molecular dynamics; Bond order potential; Nanostructures; Quantum dots; Wafer bonding

* Extended contribution published at MMM2006 [1]

Correspondence address, Dr. Kurt Scheerschmidt, Max Planck Institute of Microstructure Physics, Weinberg 2, D-06120 Halle, Germany, Tel.: +49 345 558 2910, Fax: +49 345 551 1223, E-mail:

References

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Received: 2007-4-19
Accepted: 2007-8-10
Published Online: 2013-05-23
Published in Print: 2007-11-01

© 2007, Carl Hanser Verlag, München

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https://doi.org/10.3139/146.101574
Keywords for this article
Molecular dynamics; Bond order potential; Nanostructures; Quantum dots; Wafer bonding

Articles in the same Issue

  1. Contents
  2. Contents
  3. Editorial
  4. Professor Dr. phil. Dr. techn. e. h. Hellmut F. Fischmeister
  5. Basic
  6. Compressive deformation of lamellar microstructures – a short review
  7. Influence of external and internal length scale on the flow stress of copper
  8. Spinodal decomposition of cubic Ti1−xAlxN: Comparison between experiments and modeling
  9. Combined ab-initio and N-K, Ti-L2,3, V-L2,3 electron energy-loss near edge structure studies for TiN and VN films
  10. Gold-enhanced oxidation of silicon nanowires
  11. Numerical determination of parameterised failure curves for ductile structural materials
  12. Relaxation of semiconductor nanostructures using molecular dynamics with analytic bond order potentials*
  13. Examination of phase transformations in the system Fe–N–C by means of nitrocarburising reactions and secondary annealing experiments; the α + ∊ two-phase equilibrium
  14. Applied
  15. On the evolution of secondary hardening carbides in a high-speed steel characterised by APFIM and SANS
  16. Silicon nitride tools for hot rolling of high-alloyed steel and superalloy wires – load analysis and first practical tests
  17. Development of the unloading stiffness during cyclic plastic deformation of a high-strength aluminium alloy in different tempers
  18. Enhanced thermal stability of a cobalt–boron carbide nanocomposite by ion-implantation
  19. Experimental studies and thermodynamic simulation of phase transformations in high Nb containing γ-TiAl based alloys
  20. Kinetics of nanoscale structure development during Mg-vapour reduction of tantalum oxide
  21. On the interaction of ductile damage and materials softening of a Ni-base alloy during hot deformation
  22. Adhesive contact between flat punches with finite edge radius and an elastic half-space
  23. Notifications
  24. DGM News
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