论文信息 - Relaxation of semiconductor nanostructures using molecular dynamics with analytic bond order potentials*

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

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.

K. Scheerschmidt | V. Kuhlmann

[1] K. Scheerschmidt,et al. σ -bond expression for an analytic bond-order potential: Including π and on-site terms in the fourth moment , 2007 .

[2] Haydn N. G. Wadley,et al. Analytic bond-order potential for predicting structural trends across the sp-valent elements , 2005 .

[3] K. Scheerschmidt,et al. Molecular Dynamics Investigation of Bonded Twist Boundaries , 2004 .

[4] Haydn N. G. Wadley,et al. Analytic bond-order potentials for multicomponent systems , 2004 .

[5] K. Scheerschmidt,et al. Atomic processes at bonded Si-interfaces studied by molecular dynamics: tayloring densities and bandgaps? , 2002 .

[6] Kurt Scheerschmidt,et al. EMPIRICAL BOND-ORDER POTENTIAL FOR SEMICONDUCTORS , 1998 .

[7] Aoki,et al. Bond-order potentials: Theory and implementation. , 1996, Physical review. B, Condensed matter.

[8] R. Kallman. A theorem on discrete groups and some consequences of Kazdan's thesis , 1970 .

[9] M. Planck,et al. Empirical Molecular Dynamics: Possibilities, Requirements, and Limitations , 2007 .

[10] David G. Pettifor,et al. Interatomic bond-order potentials and structural prediction , 2004 .

[11] Marius Grundmann,et al. Nano-Optoelectronics : concepts, physics and devices , 2002 .

[12] P. Werner,et al. Characterization of Structure and Composition of Quantum Dots by Transmission Electron Microscopy , 2002 .

[13] U. Gösele,et al. Atomistic study of the (001), 90° twist boundary in silicon , 1998 .