Issue 18, 2011

Incidence of the molecular organization on friction at soft polymer interfaces

Abstract

Polymer molecules strongly anchored to a solid substrate and interdigitated into bulk crosslinked elastomer have been shown recently to efficiently promote adhesion and friction between substrate and elastomer. Concerning friction, the regime of low surface coverage in surface anchored chains has been fully and quantitatively accounted for by the pull off mechanisms, where individual chains are dynamically extracted from the elastomer. Then, the stretching energy of these chains dominates the friction losses. We focus here on the dense surface coverage regime. We present systematic experiments performed on the polydimethylsiloxane (PDMS) – silica system, and determine molecular weight and sliding velocity dependences of the friction stress. We show that the friction is dominated by the shear thinning of the grafted layer confined between the elastomer and the substrate, and responding to the shear solicitation like a melt, but with very long relaxation times. We also show that the friction stress appears highly sensitive to the molecular organization inside the surface anchored polymer layer, comparing end grafted and strongly adsorbed layers having otherwise the same molecular characteristics (molecular weight of the chains, and thickness of the surface anchored layer).

Graphical abstract: Incidence of the molecular organization on friction at soft polymer interfaces

Article information

Article type
Paper
Submitted
11 May 2011
Accepted
16 Jun 2011
First published
01 Aug 2011

Soft Matter, 2011,7, 8535-8541

Incidence of the molecular organization on friction at soft polymer interfaces

C. Cohen, F. Restagno, C. Poulard and L. Léger, Soft Matter, 2011, 7, 8535 DOI: 10.1039/C1SM05874F

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