Issue 47, 2024

Finite element modelling of atomic force microscopy imaging on deformable surfaces

Abstract

Atomic force microscopy (AFM) provides a three-dimensional topographic representation of a sample surface, at nanometre resolution. Computational simulations can aid the interpretation of such representations, but have mostly been limited to cases where both the AFM probe and the sample are hard and not compressible. In many applications, however, the sample is soft and therefore deformed due to the force exerted by the AFM tip. Here we use finite element modelling (FEM) to study how the measured AFM topography relates to the surface structures of soft and compressible materials. Consistent with previous analytical studies, the measured elastic modulus in AFM is generally found to deviate from the elastic modulus of the sample material. By the analysis of simple surface geometries, the FEM modelling shows how measured mechanical and topographic features in AFM images depend on a combination of tip-sample geometry and indentation of the tip into the sample. Importantly for the interpretation of AFM data, nanoparticles may appear larger or smaller by a factor of two depending on tip size and indentation force; and a higher spatial resolution in AFM images does not necessarily coincide with a more accurate representation of the sample surface. These observations on simple surface geometries also extend to molecular-resolution AFM, as illustrated by comparing FEM results with experimental data acquired on DNA. Taken together, the FEM results provide a framework that aids the interpretation of surface topography and local mechanics as measured by AFM.

Graphical abstract: Finite element modelling of atomic force microscopy imaging on deformable surfaces

Article information

Article type
Paper
Submitted
12 Sep 2024
Accepted
14 Nov 2024
First published
15 Nov 2024
This article is Open Access
Creative Commons BY license

Soft Matter, 2024,20, 9483-9492

Finite element modelling of atomic force microscopy imaging on deformable surfaces

J. Giblin-Burnham, Y. Javanmardi, E. Moeendarbary and B. W. Hoogenboom, Soft Matter, 2024, 20, 9483 DOI: 10.1039/D4SM01084A

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