Singular dynamics in the failure of soft adhesive contacts

We characterize the mechanical recovery of compliant silicone gels following adhesive contact failure. We establish broad, stable adhesive contacts between rigid microspheres and soft gels, then stretch the gels to large deformations by pulling quasi-statically on the contact. Eventually, the adhesi...

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Bibliographic Details
Published inSoft matter Vol. 15; no. 6; pp. 1327 - 1334
Main Authors Berman, Justin D, Randeria, Manjari, Style, Robert W, Xu, Qin, Nichols, James R, Duncan, Aidan J, Loewenberg, Michael, Dufresne, Eric R, Jensen, Katharine E
Format Journal Article
LanguageEnglish
Published England Royal Society of Chemistry 2019
Subjects
Adhesive strength
Adhesives
Deformation
Gels
Microspheres
Modulus of elasticity
Self-similarity
Silicones
Solid phases
Stress relaxation
Viscous flow
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Summary:We characterize the mechanical recovery of compliant silicone gels following adhesive contact failure. We establish broad, stable adhesive contacts between rigid microspheres and soft gels, then stretch the gels to large deformations by pulling quasi-statically on the contact. Eventually, the adhesive contact begins to fail, and ultimately slides to a final contact point on the bottom of the sphere. Immediately after detachment, the gel recoils quickly with a self-similar surface profile that evolves as a power law in time, suggesting that the adhesive detachment point is singular. The singular dynamics we observe are consistent with a relaxation process driven by surface stress and slowed by viscous flow through the porous, elastic network of the gel. Our results emphasize the importance of accounting for both the liquid and solid phases of gels in understanding their mechanics, especially under extreme deformation.
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ISSN:1744-683X
1744-6848
DOI:10.1039/c8sm02075b