Issue 12, 2014

Nanoscale-resolved elasticity: contact mechanics for quantitative contact resonance atomic force microscopy

Abstract

Contact resonance atomic force microscopy (CR-AFM) constitutes a powerful approach for nanometer-resolved mechanical characterization of surfaces. Yet, absolute accuracy is frequently impaired by ad hoc assumptions on the dynamic AFM cantilever characteristics as well as contact model. Within the present study, we clarify the detailed interplay of stress fields and geometries for full quantitative understanding, employing combined experimental numerical studies for real AFM probes. Concerning contact description, a two-parameter ansatz is utilized that takes tip geometries and their corresponding indentation moduli into account. Parameter sets obtained upon experimental data fitting for different tip blunting states, are discussed in terms of model-specific artificiality versus real contact physics at the nanoscale. Unveiling the underlying physics in detail, these findings pave the way for accurate characterization of nanomechanical properties with highest resolution.

Graphical abstract: Nanoscale-resolved elasticity: contact mechanics for quantitative contact resonance atomic force microscopy

Article information

Article type
Paper
Submitted
25 Feb 2014
Accepted
21 Apr 2014
First published
16 May 2014

Nanoscale, 2014,6, 6898-6910

Author version available

Nanoscale-resolved elasticity: contact mechanics for quantitative contact resonance atomic force microscopy

A. M. Jakob, J. Buchwald, B. Rauschenbach and S. G. Mayr, Nanoscale, 2014, 6, 6898 DOI: 10.1039/C4NR01034E

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