Options
Influence of material and geometrical parameters on the adhesive performance of vibration-modulated soft contacts
Citation Link: https://doi.org/10.15480/882.17021
Publikationstyp
Journal Article
Date Issued
2026-07-01
Sprache
English
Author(s)
TORE-DOI
Volume
118
Article Number
106130
Citation
European Journal of Mechanics A Solids 118: 106130 (2026)
Publisher DOI
Scopus ID
Publisher
Elsevier
Vibroadhesion, the modulation of interfacial adhesion by superimposing small-amplitude, high-frequency vibrations on an adhesive contact, offers a simple and fast strategy to rapidly tune contact forces. A systematic understanding of how key geometrical and material parameters govern this behavior is still lacking. Here, we present a comprehensive experimental investigation of vibroadhesion in viscoelastic PDMSβglass Hertzian contacts, examining the influence of substrate thickness π‘, radius of the indenter π
, material properties like modulus and thermodynamic surface energy, unloading rate π³ and preload πcβ on the stickiness performance of vibration-modulated interfaces such as: pull-off force πββ contact radius πΆ, mean stress at pull-off Οββ, maximum enhancement with respect to the static adhesion test, range of vibration amplitudes that sustain adhesion enhancement. We find that across all tests, vibration activation triggers an abrupt expansion of the contact area, which upon unloading, results in a substantial increase of the pull-off force up to a saturation level always coinciding with the vibration level causing interfacial instabilities at the interface (wrinkles). Although the absolute value of the pull-off force may be strongly influenced by geometrical and material parameters, the maximum adhesion enhancement with respect to the reference static test remained consistently close to a 13-fold increase. We obtained the maximum mean stress at pull-off of 186 kPa when indenting with the smallest sphere. The unloading rate r weakly affects the adhesive performance and the preload Fcβ is nearly irrelevant in determining the pull-off force πββ. Taken together, these results provide both physical insights and practical guidelines for designing vibration-modulated adhesive interfaces for rapid, reversible, and tunable adhesion.
DDC Class
530.41: Mechanics of Solids
620.3: Vibrations
660: Chemistry; Chemical Engineering
Publication version
publishedVersion
Loading...
Name
1-s2.0-S0997753826001166-main.pdf
Type
Main Article
Size
6.96 MB
Format
Adobe PDF