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Spin dynamics in a Curie-switch.
A F Kravets1, A I Tovstolytkin, Yu I Dzhezherya
1Institute of Magnetism, National Academy of Sciences of Ukraine, 36 b Vernadsky Blvd., 03142 Kyiv, Ukraine. Nanostructure Physics, Royal Institute of Technology, 10691 Stockholm, Sweden.
Investigating ferromagnetic resonance in F1/f/F2/AF multilayers reveals spacer properties significantly influence resonance fields. Key magnetic parameters like exchange length and Curie temperature are crucial for understanding spin dynamics in these nanostructures.
Area of Science:
- Condensed Matter Physics
- Materials Science
- Nanotechnology
Background:
- Ferromagnetic resonance (FMR) is a key technique for probing magnetic properties of materials.
- Multilayer structures with ferromagnetic and antiferromagnetic layers offer tunable magnetic behaviors.
- Understanding interfacial effects and spacer properties is crucial for advanced magnetic devices.
Purpose of the Study:
- To investigate the ferromagnetic resonance properties of F1/f/F2/AF multilayers.
- To determine the influence of the ferromagnetic spacer layer on resonance fields.
- To identify key magnetic parameters governing FMR in these structures.
Main Methods:
- Experimental investigation of F1/f/F2/AF multilayers using ferromagnetic resonance.
- Theoretical calculations to model spacer-mediated exchange coupling effects.
- Deduction of magnetic parameters from experimental data for Ni(x)Cu(100-x) spacers.
Main Results:
- Spacer-mediated exchange coupling strongly affects resonance fields of both soft (F1) and hard (F2) ferromagnetic layers.
- Key spacer parameters identified: magnetic exchange length (Λ), effective saturation magnetization (m0), and effective Curie temperature (T(C)(eff)).
- Parameter values determined for Ni(x)Cu(100-x) spacers (x = 54–70 at. %, d = 3–6 nm).
Conclusions:
- The study provides insights into thermally-controlled spin precession and switching in magnetic nanostructures.
- Identified parameters are critical for designing and optimizing spin-based oscillators and memory devices.
- Spacer properties play a pivotal role in determining FMR behavior in complex magnetic multilayers.

