Towards Future Interfaces With Tuneable Adhesion By Dynamic Excitation

HORIZON.1.1HORIZON-ERCID: 101039198
EC Contribution
€14,998
Consortium Size
1 orgs
Summary

Macroscopic adhesion is of utmost importance in key technologies such as soft and climbing robots, aerospace grasping technologies, human-robot interactions, pick-and-place manipulators. Commonly, bioinspired adhesives interfaces have been characterized from a quasi-static perspective, neglecting the effect of dynamic excitations. Nevertheless, recent observations suggest that added micro-vibrations may be exploited to strongly enhance and rapidly tune macroscopic adhesion. By exploiting the multiplicative coupling between geometric- and viscoelastic vibration-induced enhancements of macroscopic adhesion, SURFACE aims at designing future soft interfaces with unprecedented and tuneable adhesion strength. To this end, I aim to: (i) develop highly efficient numerical tools for studying adhesion of patterned soft surfaces under micro-vibration excitation, (ii) unveil the coupling effect between topography and viscoelasticity that determine the interfacial strength and toughness (iii) design optimal surface topography and excitation for macroscopic adhesion tuning, by exploiting artificial intelligence models to unveil new mechanisms for adhesion enhancement, (iv) prove the adhesive performance reached, by experimentally testing high-resolution 3D printed interfaces with the desired topography and superposed micro-vibrations. So far, the adhesive performance of bioinspired patterned interfaces has been limited by manufacturing capabilities at the micro/nanoscale. SURFACE ground-breaking approach aims at exploiting dynamics excitation to outperform state-of-the-art adhesive interfaces. By exploiting artificial intelligence models, SURFACE aims at revealing new mechanisms for adhesion enhancement, which lay beyond our intuition. Rapidly tuneable strong adhesive interfaces have the potential to revolutionize cutting-edge technologies based on soft adhesive interfaces that require to move and place objects quickly and with accuracy.

Consortium (1)

Project Results (14)

Source: CORDIS, the EU research results database.

Publications (12)
An asymptotic model of vibroadhesion
International Journal of Non-Linear Mechanics· 2025DOI
I. Argatov, A. Papangelo, M. Ciavarella
Enhancement of adhesion strength through microvibrations: Modeling and experiments
Journal of the Mechanics and Physics of Solids· 2025DOI
Michele Tricarico, Michele Ciavarella, Antonio Papangelo
On the dynamic JKR adhesion problem
Mechanics of Materials· 2025DOI
Ciavarella, M.; Tricarico, M.; Papangelo, A.
Rapid detachment of a rigid sphere adhered to a viscoelastic substrate: An upper bound model incorporating Maugis parameter and preload effects
Journal of the Mechanics and Physics of Solids· 2025DOI
Qingao Wang, Antonio Papangelo, Michele Ciavarella, Huajian Gao, Qunyang Li
Viscoelastic friction in sliding a non-cylindrical asperity
The European Physical Journal E· 2025DOI
M. Ciavarella, M. Tricarico, A. Papangelo
Bulk and fracture process zone contribution to the rate-dependent adhesion amplification in viscoelastic broad-band materials
Journal of the Mechanics and Physics of Solids· 2024DOI
Ali Maghami, Qingao Wang, Michele Tricarico, Michele Ciavarella, Qunyang Li, Antonio Papangelo
Friction for a sliding adhesive viscoelastic cylinder: Effect of Maugis parameter
European Journal of Mechanics - A/Solids· 2024DOI
A. Papangelo, R. Nazari, M. Ciavarella
Friction in Rolling a Cylinder on or Under a Viscoelastic Substrate with Adhesion
Tribology Letters· 2024DOI
R. Nazari, A. Papangelo, M. Ciavarella
Mechanochromic Suction Cups for Local Stress Detection in Soft Robotics
Advanced Intelligent Systems· 2024DOI
Goffredo Giordano, Rob Bernardus Nicolaas Scharff, Marco Carlotti, Mariacristina Gagliardi, Carlo Filippeschi, Alessio Mondini, Antonio Papangelo, Barbara Mazzolai
Viscoelastic amplification of the pull-off stress in the detachment of a rigid flat punch from an adhesive soft viscoelastic layer
Engineering Fracture Mechanics· 2024DOI
Ali Maghami, Michele Tricarico, Michele Ciavarella, Antonio Papangelo
A two-scale FEM-BAM approach for fingerpad friction under electroadhesion
Frontiers in Mechanical Engineering· 2023DOI
Fabian Forsbach, Markus Heß, Antonio Papangelo
Detachment of a Rigid Flat Punch from a Viscoelastic Material
Tribology Letters· 2023DOI
Antonio Papangelo, Michele Ciavarella
Deliverables (1)
Data Management Plan
Other Results (1)
Periodic Reporting for period 1 - SURFACE (Towards Future Interfaces With Tuneable Adhesion By Dynamic Excitation)