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The drainage of thin liquid films between solid surfaces

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journal contribution
posted on 1985-01-01, 00:00 authored by D Chan, Roger Horn
We present measurements of the thickness as a function of time of liquid films as they are squeezed between molecularly smooth mica surfaces. Three Newtonian, nonpolar liquids have been studied: octamethylcyclotetrasiloxane, n-tetradecane, and n-hexadecane. The film thicknesses are determined with an accuracy of 0.2 nm as they drain from ∼1 μm to a few molecular layers. Results are in excellent agreement with the Reynolds theory of lubrication for film thicknesses above 50 nm. For thinner films the drainage is slower than the theoretical prediction, which can be accounted for by assuming that the liquid within about two molecular layers of each solid surface does not undergo shear. In very thin films the continuum Reynolds theory breaks down, as drainage occurs in a series of abrupt steps whose size matches the thickness of molecular layers in the liquid. The presence of trace amounts of water has a dramatic effect on the drainage of a nonpolar liquid between hydrophilic surfaces, causing film rupture which is not observed in the dry liquids.

History

Journal

Journal of chemical physics

Volume

83

Pagination

5311 - 5324

Location

New York, N. Y.

Open access

  • Yes

ISSN

0021-9606

eISSN

1089-7690

Language

eng

Notes

Reproduced with the kind permission of the copyright owner.

Publication classification

C1.1 Refereed article in a scholarly journal

Copyright notice

1985, American Institute of Physics

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