Na adsorption on the [formula presented] surface: From two-dimensional gas to nanocluster array

Kehui Wu; Y. Fujikawa; T. Nagao; Y. Hasegawa; Koji Nakayama; Q. K. Xue; E. G. Wang; T. Briere; V. Kumar; Y. Kawazoe; S. B. Zhang; T. Sakurai

doi:10.1103/PhysRevLett.91.126101

Na adsorption on the [formula presented] surface: From two-dimensional gas to nanocluster array

Kehui Wu, Y. Fujikawa, T. Nagao, Y. Hasegawa, Koji Nakayama, Q. K. Xue, E. G. Wang, T. Briere, V. Kumar, Y. Kawazoe, S. B. Zhang, T. Sakurai

Research output: Contribution to journal › Article › peer-review

8 Citations (Scopus)

Abstract

We have systematically investigated Na adsorption on the [Formula presented] surface at room temperature using scanning tunneling microscopy (STM). Below the critical coverage of 0.08 monolayer, we find intriguing contrast modulation instead of localized Na adsorbates, coupled with streaky noise in the STM images, which is accompanied by monotonic work function drop. Above the critical coverage, Na clusters emerge and form a self-assembled array. Combined with first-principles theoretical simulations, we conclude that the Na atoms on the ([Formula presented]) surface are, while strongly bound ([Formula Presented]) to the surface, highly mobile in “basins” around the Si rest atoms, forming a two-dimensional gas phase at the initial coverage, and that the cluster at the higher coverage consists of six Na atoms together with three Si adatoms.

Original language	English
Journal	Physical review letters
Volume	91
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevLett.91.126101
Publication status	Published - 2003
Externally published	Yes

ASJC Scopus subject areas

Physics and Astronomy(all)

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10.1103/PhysRevLett.91.126101

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title = "Na adsorption on the [formula presented] surface: From two-dimensional gas to nanocluster array",

abstract = "We have systematically investigated Na adsorption on the [Formula presented] surface at room temperature using scanning tunneling microscopy (STM). Below the critical coverage of 0.08 monolayer, we find intriguing contrast modulation instead of localized Na adsorbates, coupled with streaky noise in the STM images, which is accompanied by monotonic work function drop. Above the critical coverage, Na clusters emerge and form a self-assembled array. Combined with first-principles theoretical simulations, we conclude that the Na atoms on the ([Formula presented]) surface are, while strongly bound ([Formula Presented]) to the surface, highly mobile in “basins” around the Si rest atoms, forming a two-dimensional gas phase at the initial coverage, and that the cluster at the higher coverage consists of six Na atoms together with three Si adatoms.",

author = "Kehui Wu and Y. Fujikawa and T. Nagao and Y. Hasegawa and Koji Nakayama and Xue, {Q. K.} and Wang, {E. G.} and T. Briere and V. Kumar and Y. Kawazoe and Zhang, {S. B.} and T. Sakurai",

year = "2003",

doi = "10.1103/PhysRevLett.91.126101",

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volume = "91",

journal = "Physical Review Letters",

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publisher = "American Physical Society",

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TY - JOUR

T1 - Na adsorption on the [formula presented] surface

T2 - From two-dimensional gas to nanocluster array

AU - Wu, Kehui

AU - Fujikawa, Y.

AU - Nagao, T.

AU - Hasegawa, Y.

AU - Nakayama, Koji

AU - Xue, Q. K.

AU - Wang, E. G.

AU - Briere, T.

AU - Kumar, V.

AU - Kawazoe, Y.

AU - Zhang, S. B.

AU - Sakurai, T.

PY - 2003

Y1 - 2003

N2 - We have systematically investigated Na adsorption on the [Formula presented] surface at room temperature using scanning tunneling microscopy (STM). Below the critical coverage of 0.08 monolayer, we find intriguing contrast modulation instead of localized Na adsorbates, coupled with streaky noise in the STM images, which is accompanied by monotonic work function drop. Above the critical coverage, Na clusters emerge and form a self-assembled array. Combined with first-principles theoretical simulations, we conclude that the Na atoms on the ([Formula presented]) surface are, while strongly bound ([Formula Presented]) to the surface, highly mobile in “basins” around the Si rest atoms, forming a two-dimensional gas phase at the initial coverage, and that the cluster at the higher coverage consists of six Na atoms together with three Si adatoms.

AB - We have systematically investigated Na adsorption on the [Formula presented] surface at room temperature using scanning tunneling microscopy (STM). Below the critical coverage of 0.08 monolayer, we find intriguing contrast modulation instead of localized Na adsorbates, coupled with streaky noise in the STM images, which is accompanied by monotonic work function drop. Above the critical coverage, Na clusters emerge and form a self-assembled array. Combined with first-principles theoretical simulations, we conclude that the Na atoms on the ([Formula presented]) surface are, while strongly bound ([Formula Presented]) to the surface, highly mobile in “basins” around the Si rest atoms, forming a two-dimensional gas phase at the initial coverage, and that the cluster at the higher coverage consists of six Na atoms together with three Si adatoms.

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JF - Physical Review Letters

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Na adsorption on the [formula presented] surface: From two-dimensional gas to nanocluster array

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