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Main Authors: Okamoto, Kazuma, Imura, Takumi, Abo, Satoshi, Wakaya, Fujio, Murakami, Katsuhisa, Nagao, Masayoshi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.06563
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_version_ 1866913784804671488
author Okamoto, Kazuma
Imura, Takumi
Abo, Satoshi
Wakaya, Fujio
Murakami, Katsuhisa
Nagao, Masayoshi
author_facet Okamoto, Kazuma
Imura, Takumi
Abo, Satoshi
Wakaya, Fujio
Murakami, Katsuhisa
Nagao, Masayoshi
contents A method to measure the electrical resistivity of materials using magnetic-force microscopy (MFM) is discussed, where MFM detects the magnetic field caused by the tip-oscillation-induced eddy current. To achieve high sensitivity, a high cantilever oscillation frequency is preferable, because it induces large eddy currents in the material. Higher-order resonance modes of the cantilever oscillation leads to higher frequency. To discuss such high-order-mode oscillation, a differential equation governing MFM cantilever oscillation in the high-order resonance mode is formulated, and an analytical solution of the phase difference is obtained. The result shows that the phase difference decreases at higher modes, because the effective spring constant increases faster than the force from the eddy current.
format Preprint
id arxiv_https___arxiv_org_abs_2504_06563
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Resistivity measurement for non-magnetic materials using high-order resonance mode of mfm-cantilever oscillation
Okamoto, Kazuma
Imura, Takumi
Abo, Satoshi
Wakaya, Fujio
Murakami, Katsuhisa
Nagao, Masayoshi
Materials Science
Instrumentation and Detectors
A method to measure the electrical resistivity of materials using magnetic-force microscopy (MFM) is discussed, where MFM detects the magnetic field caused by the tip-oscillation-induced eddy current. To achieve high sensitivity, a high cantilever oscillation frequency is preferable, because it induces large eddy currents in the material. Higher-order resonance modes of the cantilever oscillation leads to higher frequency. To discuss such high-order-mode oscillation, a differential equation governing MFM cantilever oscillation in the high-order resonance mode is formulated, and an analytical solution of the phase difference is obtained. The result shows that the phase difference decreases at higher modes, because the effective spring constant increases faster than the force from the eddy current.
title Resistivity measurement for non-magnetic materials using high-order resonance mode of mfm-cantilever oscillation
topic Materials Science
Instrumentation and Detectors
url https://arxiv.org/abs/2504.06563