Adhesion of Elastic Thin Films: Double Peeling of Tapes Versus Axisymmetric Peeling of Membranes

• Published in: Tribology letters Vol. 52; no. 3; pp. 439 - 447
• Main Authors: Afferrante, L., Carbone, G., Demelio, G., Pugno, N.
• Format: Journal Article
• Language: English
• Published: Boston Springer US 01.12.2013; Springer Nature B.V
• Subjects: Axisymmetric; Chemistry and Materials Science; Corrosion and Coatings; Detaching; Detachment; Exact solutions; Interfacial energy; Materials Science; Mathematical analysis; Membranes; Modulus of elasticity; Nanotechnology; Numerical analysis; Original Paper; Peeling; Physical Chemistry; Polymethyl methacrylate; Polymethyl methacrylates; Substrates; Surfaces and Interfaces; Theoretical and Applied Mechanics; Thin Films; Tribology; Workflow; Energy release rate; Fracture; Peeling; Double peeling; Adhesion; Peeling of thin membranes
• ISSN: 1023-8883; 1573-2711
• DOI: 10.1007/s11249-013-0227-6

The mechanism of detachment of thin films from a flat smooth rigid substrate is investigated. In particular, analytical solutions in closed form are proposed for the double peeling of an elastic tape as well as for the axisymmetric peeling of a membrane. We show that in the case of double peeling of an endless elastic tape, a critical value of the pull-off force is found, above which the tape is completely detached from the substrate. In particular, as the detachment process advances, the peeling angle is stabilized on a limiting value, which only depends on the geometry of the tape, its elastic modulus and on the interfacial energy Δ γ . This predicted behavior agrees with the “theory of multiple peeling” and clarifies some aspects of this theory. Moreover, it is also corroborated by experimental results (work in progress) we are carrying out on a standard adhesive tape adhered to a smooth flat poly(methyl methacrylate) surface. In the case of the axisymmetric adhering membrane, a different behavior is observed. In such case, the system is always stable, and the detached area monotonically increases with the peeling force, i.e., the elastic membrane can sustain in principle any applied force. Results are validated by a fully numerical analysis performed with the aid of a finite element commercial software.