Million-atom molecular dynamics simulation by order-N electronic
  structure theory and parallel computation

Bachlechner M. E.; Broughton J. Q.; Car R.; Donohue J.; Goedecker S.; Harrison W. A.; Hoshi T.; Hoshi T.; Hoshi T.; Kwon I.; McSkimin H. J.; Nielsen O. H.; Ordejón P.

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Million-atom molecular dynamics simulation by order-N electronic structure theory and parallel computation

Authors: Bachlechner M. E.
Broughton J. Q.
Car R.
Donohue J.
Goedecker S.
Harrison W. A.
Hoshi T.
Hoshi T.
Hoshi T.
Kwon I.
McSkimin H. J.
Nielsen O. H.
Ordejón P.
Publication date: 18 June 2003
Publisher: 'Japan Society of Applied Physics'
Doi

Abstract

Parallelism of tight-binding molecular dynamics simulations is presented by means of the order-N electronic structure theory with the Wannier states, recently developed (J. Phys. Soc. Jpn. 69,3773 (2000)). An application is tested for silicon nanocrystals of more than millions atoms with the transferable tight-binding Hamiltonian. The efficiency of parallelism is perfect, 98.8 %, and the method is the most suitable to parallel computation. The elapse time for a system of

2\times 10^6

atoms is 3.0 minutes by a computer system of 64 processors of SGI Origin 3800. The calculated results are in good agreement with the results of the exact diagonalization, with an error of 2 % for the lattice constant and errors less than 10 % for elastic constants.Comment: 5 pages, 3 figure

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