Static and Dry Friction due to Multiscale Surface Roughness

C. Grossiord; C. Kittel; G. A. Tomlinson; G. C. Spencer; J. B. Sokoloff; J. Feder; J.-M. Martin; J.-M. Martin; K. L. Johnson; M. Brillouin; M. H. Muser; M. Hirano; N. W. Ashcroft; P. Lemoine; S. Aubry

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Static and Dry Friction due to Multiscale Surface Roughness

Authors: C. Grossiord
C. Kittel
G. A. Tomlinson
G. C. Spencer
J. B. Sokoloff
J. Feder
J.-M. Martin
J.-M. Martin
K. L. Johnson
M. Brillouin
M. H. Muser
M. Hirano
N. W. Ashcroft
P. Lemoine
S. Aubry
Publication date: 13 May 2008
Publisher: 'American Physical Society (APS)'
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Abstract

It is shown on the basis of scaling arguments that a disordered interface between two elastic solids will quite generally exhibit static and "dry friction" (i.e., kinetic friction which does not vanish as the sliding velocity approaches zero), because of Tomlinson model instabilities that occur for small length scale asperities. This provides a possible explanation for why static and "dry" friction are virtually always observed, and superlubricity almost never occurs

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