Krylov Subspace Method for Molecular Dynamics Simulation based on
  Large-Scale Electronic Structure Theory

Andersen O. K.; Arfken G. B.; Chadi D. J.; Dronskowski R.; Fu C. C.; Galli G.; Geshi M.; Golub G. H.; Haydock R.; Haydock R.; Haydock R.; Hoshi T.; Hoshi T.; Hoshi T.; Hoshi T.; Kohn W.; Kwon I.; Ordejón P.; Ozaki T.; Ozaki T.; Pollman J.; Ramstad A.; van der Vorst H. A.; Wu S. Y.

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Krylov Subspace Method for Molecular Dynamics Simulation based on Large-Scale Electronic Structure Theory

Authors: Andersen O. K.
Arfken G. B.
Chadi D. J.
Dronskowski R.
Fu C. C.
Galli G.
Geshi M.
Golub G. H.
Haydock R.
Haydock R.
Haydock R.
Hoshi T.
Hoshi T.
Hoshi T.
Hoshi T.
Kohn W.
Kwon I.
Ordejón P.
Ozaki T.
Ozaki T.
Pollman J.
Ramstad A.
van der Vorst H. A.
Wu S. Y.
Publication date: 18 March 2004
Publisher: 'Japan Society of Applied Physics'
Doi

Abstract

For large scale electronic structure calculation, the Krylov subspace method is introduced to calculate the one-body density matrix instead of the eigenstates of given Hamiltonian. This method provides an efficient way to extract the essential character of the Hamiltonian within a limited number of basis set. Its validation is confirmed by the convergence property of the density matrix within the subspace. The following quantities are calculated; energy, force, density of states, and energy spectrum. Molecular dynamics simulation of Si(001) surface reconstruction is examined as an example, and the results reproduce the mechanism of asymmetric surface dimer.Comment: 7 pages, 3 figures; corrected typos; to be published in Journal of the Phys. Soc. of Japa

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