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High-Speed Dynamics, Damping, and Relaxation Times in Submicrometer Spin-Valve Devices

Published

Author(s)

Stephen E. Russek, Shehzaad F. Kaka, Michael J. Donahue

Abstract

The dynamical response of spin-vale devices with linewidths of 0.8 5m has been measured after excitation with 160 ps magnetic impulses. The devices show resonant frequencies of 2-4 GHz which determine the upper limit of their operation frequency. The dynamical response can be fit with Landau-Lifshitz models to extract an effective uniform-mode damping constant, αum. The measured values of αum were between 0.04 and 0.01 depending on the magnitude of the longitudinal bias field. The appropriate damping coefficient for use in micromagnetic modeling, αmn was extracted from the dynamical response with large longitudinal bias field. This value was used to model the switching of a 0.1 5m x 1.0 5m magnetoresistive random access memory cell. The micromagnetic model included shape disorder that is expected to be found in real devices. The simulations showed that, while the magnetization reverses rapidly (<0.5 ns), it took several nanoseconds for the energy to be removed from the magnetic system. The switching energy was stored in short wavelength magnetic fluctuations that could dramatically affect the re-reversal process 1-2 ns after the first reversal.
Citation
Journal of Applied Physics
Volume
87
Issue
9

Keywords

damping, high-speed dynaics, landau-Fifshitz models, MRAM, spin-valve

Citation

Russek, S. , Kaka, S. and Donahue, M. (2000), High-Speed Dynamics, Damping, and Relaxation Times in Submicrometer Spin-Valve Devices, Journal of Applied Physics, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=30205 (Accessed November 23, 2024)

Issues

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Created April 30, 2000, Updated October 12, 2021