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Main Authors: Umeda, Kenichi, Kamoshita, Karen, Kodera, Noriyuki
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.18748
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author Umeda, Kenichi
Kamoshita, Karen
Kodera, Noriyuki
author_facet Umeda, Kenichi
Kamoshita, Karen
Kodera, Noriyuki
contents Amplitude-modulation atomic force microscopy (AM-AFM) measures nanoscale surface structures by detecting changes in the cantilever oscillation amplitude, contributing to materials research. AM-AFM can non-destructively observe fragile molecules, such as biomolecules, even while the probe is in intermittent contact with the sample. However, it remains unclear why the tip-sample interaction force estimated from an experimental amplitude value is substantially greater than the actual molecular binding force, despite the successful visualization of molecular dynamics. Here, we formulate a quantitative force conversion equation for arbitrary driving frequencies. Comprehensive theoretical analysis reveals that when the cantilever is excited at the resonance slope, the conventional equation overestimates the actual force by approximately five times, as it is valid only for excitation at the resonance frequency. The theory is validated by simulations and experiments and can be applied to various AM-AFM applications in materials research.
format Preprint
id arxiv_https___arxiv_org_abs_2407_18748
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Quantitative Formulation of Frequency-Dependent Average Force in AM-AFM
Umeda, Kenichi
Kamoshita, Karen
Kodera, Noriyuki
Applied Physics
Amplitude-modulation atomic force microscopy (AM-AFM) measures nanoscale surface structures by detecting changes in the cantilever oscillation amplitude, contributing to materials research. AM-AFM can non-destructively observe fragile molecules, such as biomolecules, even while the probe is in intermittent contact with the sample. However, it remains unclear why the tip-sample interaction force estimated from an experimental amplitude value is substantially greater than the actual molecular binding force, despite the successful visualization of molecular dynamics. Here, we formulate a quantitative force conversion equation for arbitrary driving frequencies. Comprehensive theoretical analysis reveals that when the cantilever is excited at the resonance slope, the conventional equation overestimates the actual force by approximately five times, as it is valid only for excitation at the resonance frequency. The theory is validated by simulations and experiments and can be applied to various AM-AFM applications in materials research.
title Quantitative Formulation of Frequency-Dependent Average Force in AM-AFM
topic Applied Physics
url https://arxiv.org/abs/2407.18748