Single hydrogen atoms on the Si(001) surface

Radny, M. W.; Smith, P. V.; Reusch, T. C. G; Warschkow, O.; Marks, N. A.; Wilson, H. F.; Schofield, S. R.; Curson, N. J.; McKenzie, D. R.; Simmons, M. Y.

Title: Single hydrogen atoms on the Si(001) surface
Creator: Radny, M. W.; Smith, P. V.; Reusch, T. C. G; Warschkow, O.; Marks, N. A.; Wilson, H. F.; Schofield, S. R.; Curson, N. J.; McKenzie, D. R.; Simmons, M. Y.
Relation: Physical Review B: Condensed Matter and Materials Physics Vol. 76, Issue 15
Publisher Link: http://dx.doi.org/10.1103/PhysRevB.76.155302
Publisher: American Physical Society
Resource Type: journal article
Date: 2007
Description: Chemisorption of a single hydrogen atom on the n-type Si(001) surface is investigated by scanning tunneling microscopy (STM) and first-principles density functional theory (DFT) calculations. The STM experiments show that the formation of a hemihydride induces static buckling of the neighboring Si-Si dimers and suggest that different buckling configurations of these dimers are observed at negative and positive biases. They also show that the appearance of an isolated Si-Si-H hemihydride on Si(001) exhibits a complex voltage dependence with the brightness of the dangling bond of the hemihydride changing significantly at negative sample bias. DFT calculations predict two stable, ground state atomic configurations for the hemihydride on Si(001). These correspond to parallel and antiparallel configurations of the Si-Si-H hemihydride with respect to the neighboring bare Si-Si dimers. In order to understand the bias-dependent appearance in the STM images of the n-type Si(001) surface, we include the effect of hemihydride charging due to tip-induced band bending. In filled state, the STM images are shown to result from the electronic and structural features that originate from the charge-dependent parallel configuration. In empty state, the energetics and STM measurements support the charge independent antiparallel configuration, while either structure can produce simulated images consistent with experiment.
Subject: buckling; chemisorption; dangling bonds; density functional theory; electronic structure; elemental semiconductors; hydrogen; scanning tunnelling microscopy; silicon; surface chemistry
Identifier: http://hdl.handle.net/1959.13/33765
Identifier: uon:3289
Identifier: ISSN:1098-0121
Language: eng
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