All-Optical Study of Tunable Ultrafast Spin Dynamics in [Co/Pd]-NiFe Systems: The Role of Spin-Twist Structure on Gilbert Damping

TL;DR

This study explores how the spin-twist structure in [Co/Pd]-NiFe systems influences ultrafast magnetization dynamics and Gilbert damping, revealing tunable damping behavior related to spin distribution and anisotropy effects.

Contribution

It provides new insights into the role of spin-twist structures and anisotropy in controlling ultrafast spin dynamics and damping in layered magnetic systems.

Findings

Spin-wave spectra transition from multimode to single-mode with increasing t.

Damping coefficient exhibits nonmonotonic dependence on t, with a minimum at 7.5 nm.

Ultrafast demagnetization time depends on spin distribution and spin-orbit coupling.

Abstract

We investigate optically induced ultrafast magnetization dynamics in [Co(0.5 nm)/Pd(1 nm)]x5/NiFe(t) exchange-spring samples with tilted perpendicular magnetic anisotropy using a time-resolved magneto-optical Kerr effect magnetometer. The competition between the out-of-plane anisotropy of the hard layer, the in-plane anisotropy of the soft layer and the applied bias field reorganizes the spins in the soft layer, which are modified further with the variation in t. The spin-wave spectrum, the ultrafast demagnetization time, and the extracted damping coefficient all depend on the spin distribution in the soft layer, while the latter two also depend on the spin-orbit coupling between the Co and Pd layers. The spin-wave spectra change from multimode to single-mode as t increases. At the maximum field reached in this study, H=2.5 kOe, the damping shows a nonmonotonic dependence on t with a minimum at t=7.5 nm. For t<7.5 nm, intrinsic effects dominate, whereas for t>7.5 nm, extrinsic effects govern the damping mechanisms.