Interfacial strength dominates fold formation in microscale, soft static friction

TL;DR

This study reveals that interfacial strength, rather than adhesion energy, primarily governs fold formation in microscale soft static friction, combining experimental and simulation approaches.

Contribution

It demonstrates that interfacial strength dominates fold formation in soft static friction, challenging the focus on adhesion energy alone.

Findings

Interfacial strength controls fold nucleation.

Folds form at high lateral resistance.

Adhesion energy alone does not predict folding.

Abstract

Utilizing colloidal probe, lateral force microscopy and simultaneous confocal microscopy, combined with finite element analysis, we investigate the mechanism of static friction for a microparticle on a soft, adhesive surface. We find that the surface can form a self-contacting fold at the leading front, which results from a buildup of compressive stress. A sufficiently high lateral resistance is required for folding to occur, although the folds themselves do not increase the peak force. Experimentally, folds are observed on substrates that exhibit both high and low normal adhesion, motivating the use of simulations to consider the role of adhesion energy and interfacial strength. Our simulations illustrate that the interfacial strength plays a dominating role in the formation of folds, rather than the overall adhesion energy. These results reveal that adhesion energy alone is not sufficient to predict the nucleation of folds or the lateral force, but instead the specific parameters that define the adhesion energy must be considered.