Indentation of solid membranes on rigid substrates with Van-der-Waals attraction

Abstract

We revisit the indentation of a thin solid sheet of size Rsheet suspended on a circular hole of radius R Rsheet in a smooth rigid substrate, addressing the effects of boundary conditions at the hole's edge. Introducing a basic theoretical model for the Van-der-Waals (VdW) sheet-substrate attraction, we demonstrate the dramatic effect of replacing the clamping condition (Schwerin model) with a sliding condition, whereby the supported part of the sheet is allowed to slide towards the indenter and relax the induced hoop compression through angstrom-scale deflections from the thermodynamic equilibrium (determined by the VdW potential). We highlight the possibility that the indentation force F may not exhibit the commonly anticipated cubic dependence on the indentation depth (F δ3), in which the proportionality constant is governed by the sheet's stretching modulus and the hole's radius R, but rather a pseduo-linear response, F δ, whereby the proportionality constant is governed by the bending modulus, the VdW attraction, and the sheet's size Rsheet R.