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Nanosecond Magnetization Reversal in High Coercivity Thin Films

Published

Author(s)

N D. Rizzo, Thomas J. Silva, Anthony B. Kos

Abstract

We used a wide-field Kerr microscope to measure magnetization reversal in high coercivity thin film media that were subjected to nanosecond field pulses. Coplanar waveguides were used as a field source. Two different samples of CoCr10Ta4 were measured. Sample A had a coercivity of 83 kA/m and sample B had a coercivity of 167 kA/m. For sample A, we find that after a step change in H. the magnetization initially relaxes exponentiallywith a time constant of 5 ns, and then relaxes logarithmically. We interpret this result as indicating a transition from dynamic reversal to thermal relaxation. In higher fields, the exponential relaxation time decreases according to τ = Sw/(H - Ho). where Sw = 29.7 5s 7 A 7 m-1(373 ns 7 Oe). For sample B, only logarithmic relaxation is observed, implying that the dynamic magnetization response time is subnanosecond. We observe correlated regions of reversed magnetization in our Kerr images of sample A with a typical correlation length of 1 5m along the applied field direction. We propose a microscopic model of nucleation and growth of reversed regions by analogy to viscous domain wall motion.
Citation
IEEE Transactions on Magnetics
Volume
36
Issue
1

Keywords

coplanar, high speed magnetization reversal, Kerr microscope, thinfilm media, waveguide

Citation

Rizzo, N. , Silva, T. and Kos, A. (2000), Nanosecond Magnetization Reversal in High Coercivity Thin Films, IEEE Transactions on Magnetics (Accessed December 22, 2024)

Issues

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Created December 31, 1999, Updated October 12, 2021