Layering of a liquid metal in contact with a hard wall

Layering of a liquid metal in contact with a hard wall

When a liquid makes contact with a solid wall, theoretical studies indicate that the atoms or molecules will become layered adjacent to the wall, giving rise to an oscillatory density profile. This expectation has not, however, been directly verified, although an oscillatory force curve is seen for...

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Bibliographic Details
Published in:Nature (London) Vol. 390; no. 6658; pp. 379 - 381
Main Authors: van der Veen, J. Friso, Huisman, Willem Jan, Peters, Joost F, Zwanenburg, Michel J, de Vries, Steven A, Derry, Trevor E, Abernathy, Douglas
Format: Journal Article
Language:English
Published: London Nature Publishing 27-11-1997
Nature Publishing Group
Subjects:
Chemistry
Diffraction and scattering
Exact sciences and technology
Fundamental areas of phenomenology (including applications)
Gallium
General and physical chemistry
General, apparatus
Metals
Optics
Physics
Surface and interface chemistry
Surface physical chemistry
Wave optics
X-rays
Electromagnetic wave scattering
Gallium
Liquid solid interface
Diamonds
X radiation
Liquid metals
Experimental study
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Summary:When a liquid makes contact with a solid wall, theoretical studies indicate that the atoms or molecules will become layered adjacent to the wall, giving rise to an oscillatory density profile. This expectation has not, however, been directly verified, although an oscillatory force curve is seen for liquids compressed between solid surfaces. Here we present the results of an X-ray scattering study of liquid gallium metal in contact with a (111) diamond surface. We see pronounced layering in the liquid density profile which decays exponentially with increasing distance from the wall. The layer spacing is about 3.8 å, which is equal to the repeat distance of (001) planes of upright gallium dimers in solid α-gallium. Thus it appears that the liquid near thewall assumes a solid-like structure similar to the α-phase, which is nucleated on freezing at lower temperatures. This kind of ordering should significantly influence flow, capillary osmosis, lubrication and wetting properties,, and is likely to trigger heterogeneous nucleation of the solid.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0028-0836
1476-4687
DOI:10.1038/37069