Ferromagnetic resonance of hollow micron-sized magnetic cylinders

Ferromagnetic resonance of hollow micron-sized magnetic cylinders

We have explored dynamic magnetic properties of micron-sized Ni-coated carbon fibers embedded in a polymer matrix for electromagnetic interference shielding applications. These hollow magnetic cylinders exhibit unusual dynamic magnetic properties, which were measured with a broad-band ferromagnetic...

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Bibliographic Details
Published in:Applied physics letters Vol. 121; no. 20
Main Authors: Couture, P., Goldman, S., Camley, R. E., Iacocca, E., Livesey, K. L., Robinson, T., Meyers, D., Maat, S., Nembach, H. T., Celinski, Z.
Format: Journal Article
Language:English
Published: Melville American Institute of Physics 14-11-2022
Subjects:
Applied physics
Carbon fiber reinforced plastics
Coated fibers
Cylinders
Electromagnetic interference
Electromagnetic shielding
Ferromagnetic resonance
Ferromagnetism
Magnetic properties
Magnetic shielding
Mathematical models
Nanowires
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Summary:We have explored dynamic magnetic properties of micron-sized Ni-coated carbon fibers embedded in a polymer matrix for electromagnetic interference shielding applications. These hollow magnetic cylinders exhibit unusual dynamic magnetic properties, which were measured with a broad-band ferromagnetic resonance system (FMR). We observe three families of FMR modes, which are connected to different physical locations within the cylinder. We develop a simple analytic model to explain these results and corroborate resonant mode profiles with micromagnetic simulations. We find excellent agreement between experimental results and theoretical models. Our work indicates that global demagnetizing factors are not appropriate for understanding the spin motions in these hollow cylinders. The FMR absorption observed in these hallow cylinders is very different from those observed in nanowires or solid cylinders. The field-swept envelope of all the observed FMR resonances is very broad, approximately μ 0 H = 1 T, with a linewidth of individual modes around μ 0 Δ H = 250 mT. This can be important for electromagnetic shielding applications.
ISSN:0003-6951
1077-3118
DOI:10.1063/5.0124550