Cylindrical lateral depth-sensing indentation testing of thin transversely isotropic elastic films: Incompressible and weakly compressible materials

TL;DR

This paper introduces a cylindrical lateral depth-sensing indentation method for thin transversely isotropic elastic films, enabling the extraction of elastic moduli for incompressible and weakly compressible materials, with applications in biological tissues.

Contribution

It develops a novel indentation testing technique using a cylindrical indenter for thin transversely isotropic films, including models for incompressible and weakly compressible materials.

Findings

Method accurately recovers three elastic moduli.

Applicable to biological tissues with weak compressibility.

Provides asymptotic model fitting for depth data.

Abstract

An indentation testing method, which utilizes lateral contact of a long cylindrical indenter, is developed for a thin transversely isotropic incompressible elastic film deposited onto a smooth rigid substrate. It is assumed that the material symmetry plane is orthogonal to the substrate surface, and the film thickness is small compared to the cylinder indenter length. The presented testing methodology is based on a least squares best fit of the first-order asymptotic model to the depth-sensing indentation data for recovering three independent elastic moduli which characterize an incompressible transversely isotropic material. The case of a weakly compressible material, which is important for biological tissues, is also discussed.