Issue 12, 2022

Nanomechanics of self-assembled surfactants revealed by frequency-modulation atomic force microscopy

Abstract

Surfactants play a critical role in bottom-up nanotechnologies due to their peculiar nature of controlling the interfacial energy. Since their operational mechanism originates from the molecular-scale formation and disruption processes of molecular assemblies (i.e., micelles), conventional static-mode atomic force microscopy has made a significant contribution to unravel the detailed molecular pictures. Recently, we have successfully developed a local solvation measurement technique based on three-dimensional frequency-modulation atomic force microscopy, whose spatial resolution is not limited by jump-to-contact. Here, using this novel technique, we investigate molecular nanomechanics in the formation and disruption processes of micelles formed on a hydrophobic surface. Furthermore, an experiment employing a hetero-nanostructure reveals that the nanomechanics depends on the form of the molecular assembly. Namely, the hemifusion and disruption processes are peculiar to the micellar surface and cause a higher energy dissipation than the monolayer surface. The technique established in this study will be used as a generic technology for further development of bottom-up nanotechnologies.

Graphical abstract: Nanomechanics of self-assembled surfactants revealed by frequency-modulation atomic force microscopy

Supplementary files

Article information

Article type
Paper
Submitted
20 Jan 2022
Accepted
01 Mar 2022
First published
02 Mar 2022

Nanoscale, 2022,14, 4626-4634

Author version available

Nanomechanics of self-assembled surfactants revealed by frequency-modulation atomic force microscopy

K. Umeda, K. Kobayashi and H. Yamada, Nanoscale, 2022, 14, 4626 DOI: 10.1039/D2NR00369D

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