Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations
Microscopic characterization of magnetic nanomaterials by magnetic probe interacting with ferromagnetic nano-domains is proposed according to finite-element magnetostatic field simulations. Magnetic forces detected by microscopic probe are systematically investigated on magnetic moment orientation,...
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sg-ntu-dr.10356-1651312023-03-17T15:39:32Z Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations Zheng, Xiao-Xia Sun, Weifeng School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Magnetic Forcemicroscopy Ferromagnetic Nanomaterial Microscopic characterization of magnetic nanomaterials by magnetic probe interacting with ferromagnetic nano-domains is proposed according to finite-element magnetostatic field simulations. Magnetic forces detected by microscopic probe are systematically investigated on magnetic moment orientation, magnetization intensity and geometry of ferromagnetic nano-domains, and especially on permanent magnetic coating thickness and tilting angle of probe, to provide a theoretical basis for developing magnetic force microscopy. Magnetic force direction is primarily determined by magnetic moment orientation of nanosample, and the tip curvature dominates magnetic force intensity that is meanwhile positively correlated with nanosample magnetization and probe magnetic coating thickness. Nanosample should reach a critical thickness determined by its transverse diameter to be capable of accurately detecting the magnetic properties of ferromagnetic nanomaterials. Magnetic force signal relies on probe inclination when the sample magnetic moment is along probe tilting direction, which, however, is not disturbed by probe inclination when sample magnetic moment is perpendicular to probe tilting plane. Within the geometry of satisfying a critical size requirement, the magnetic force can successfully image the ferromagnetic nano-domains by characterizing their sizes and magnetic moment orientations. The present study is expected to provide effective analyzing schemes and theoretical evidences for magnetic force microscopy of characterizing magnetic structures in ferromagnetic nanomaterials. Published version This research was funded by the National Natural Science Foundation of China (Grant No. 51337002). 2023-03-14T06:31:35Z 2023-03-14T06:31:35Z 2022 Journal Article Zheng, X. & Sun, W. (2022). Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations. Nanomaterials, 12(13), 12132212-. https://dx.doi.org/10.3390/nano12132212 2079-4991 https://hdl.handle.net/10356/165131 10.3390/nano12132212 35808048 2-s2.0-85132941215 13 12 12132212 en Nanomaterials © 2022 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https:// creativecommons.org/licenses/by/ 4.0/). application/pdf |
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Engineering::Electrical and electronic engineering Magnetic Forcemicroscopy Ferromagnetic Nanomaterial Zheng, Xiao-Xia Sun, Weifeng Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations |
| description |
Microscopic characterization of magnetic nanomaterials by magnetic probe interacting with ferromagnetic nano-domains is proposed according to finite-element magnetostatic field simulations. Magnetic forces detected by microscopic probe are systematically investigated on magnetic moment orientation, magnetization intensity and geometry of ferromagnetic nano-domains, and especially on permanent magnetic coating thickness and tilting angle of probe, to provide a theoretical basis for developing magnetic force microscopy. Magnetic force direction is primarily determined by magnetic moment orientation of nanosample, and the tip curvature dominates magnetic force intensity that is meanwhile positively correlated with nanosample magnetization and probe magnetic coating thickness. Nanosample should reach a critical thickness determined by its transverse diameter to be capable of accurately detecting the magnetic properties of ferromagnetic nanomaterials. Magnetic force signal relies on probe inclination when the sample magnetic moment is along probe tilting direction, which, however, is not disturbed by probe inclination when sample magnetic moment is perpendicular to probe tilting plane. Within the geometry of satisfying a critical size requirement, the magnetic force can successfully image the ferromagnetic nano-domains by characterizing their sizes and magnetic moment orientations. The present study is expected to provide effective analyzing schemes and theoretical evidences for magnetic force microscopy of characterizing magnetic structures in ferromagnetic nanomaterials. |
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School of Electrical and Electronic Engineering |
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School of Electrical and Electronic Engineering Zheng, Xiao-Xia Sun, Weifeng |
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Article |
| author |
Zheng, Xiao-Xia Sun, Weifeng |
| author_sort |
Zheng, Xiao-Xia |
| title |
Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations |
| title_short |
Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations |
| title_full |
Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations |
| title_fullStr |
Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations |
| title_full_unstemmed |
Magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations |
| title_sort |
magnetic force probe characterizations of nanoscaled ferromagnetic domains: finite-element magnetostatic simulations |
| publishDate |
2023 |
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https://hdl.handle.net/10356/165131 |
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1761781278200299520 |