Sample Corrugation Affects the Apparent Bond Lengths in Atomic Force Microscopy

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Access status: Embargo until 2050-01-01 , 17r.pdf (706.04 KB)

Publication date

2014-03

Authors

Boneschanscher, Mark P.ISNI 0000000419520794
Hamalainen, Sampsa K.
Liljeroth, PeterISNI 0000000392164565
Swart, IngmarORCID 0000-0003-3201-7301ISNI 0000000390199991

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Abstract

Frequency modulation atomic force microscopy (AFM) allows the chemical structure of planar molecules to be determined with atomic resolution. Typically, these measurements are carried out in constant-height mode using carbon monoxide (CO) terminated tips. Such tips exhibit considerable flexibility, i.e., the CO molecule can bend laterally due to the tip sample interaction. Using epitaxial graphene as a model system, we demonstrate experimentally that the apparent atomic positions measured by AFM depend on the sample corrugation. Using molecular mechanics simulations, we explain these observations by the interplay of the CO bending and the nonlinear background signal arising from the neighboring atoms. These effects depend nontrivially on the tip sample distance and limit the achievable accuracy on the bond length determination based on AFM experiments.

Keywords

atomic force microscopy, bond length, tip relaxation, corrugation, graphene, SCANNING PROBE MICROSCOPY, SINGLE-MOLECULE, GRAPHENE MOIRE, REAL-SPACE, IDENTIFICATION, SPECTROSCOPY

Citation

Boneschanscher, M P, Hamalainen, S K, Liljeroth, P & Swart, I 2014, 'Sample Corrugation Affects the Apparent Bond Lengths in Atomic Force Microscopy', ACS Nano, vol. 8, no. 3, pp. 3006-3014. https://doi.org/10.1021/nn500317r