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Autori principali: Walz, C., Weber, F. -C., Zeuschner, S. -P., Dumesnil, K., von Reppert, A., Bargheer, M.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2505.21211
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author Walz, C.
Weber, F. -C.
Zeuschner, S. -P.
Dumesnil, K.
von Reppert, A.
Bargheer, M.
author_facet Walz, C.
Weber, F. -C.
Zeuschner, S. -P.
Dumesnil, K.
von Reppert, A.
Bargheer, M.
contents We investigate strain-induced contributions to the transient polar magneto-optical Kerr effect response in laser-excited terfenol. The tr-MOKE signals obtained from TbFe$_{2}$ films with and without glass capping exhibit distinct signatures associated with transient strain. We experimentally observe the arrival of strain pulses via the reflectivity change. The tr-MOKE response measured without changing the pump-probe geometry is delayed by several picoseconds. This suggests a genuine magnetization response as opposed to instantaneous changes of optical constants as the origin of the signal. We model the propagation of longitudinal acoustic picosecond strain pulses and incorporate the inverse magnetostriction effect via a magnetoelastic term in the effective field of the Landau-Lifshitz-Gilbert equation with large damping. This reproduces not only the delay of the pulsed response, but also unveils the dominant contribution of quasi-static strain to the magnetization dynamics due to the thermal expansion in the optically probed near-surface region. Our experiments exemplify that purely longitudinal strain along the out-of-plane direction of the thin film enables efficient magnetoelastic coupling via the shear strain components arising in the oblique crystallographic frame of reference.
format Preprint
id arxiv_https___arxiv_org_abs_2505_21211
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Large strain contribution to the laser-driven magnetization response of magnetostrictive TbFe$_{2}$
Walz, C.
Weber, F. -C.
Zeuschner, S. -P.
Dumesnil, K.
von Reppert, A.
Bargheer, M.
Materials Science
We investigate strain-induced contributions to the transient polar magneto-optical Kerr effect response in laser-excited terfenol. The tr-MOKE signals obtained from TbFe$_{2}$ films with and without glass capping exhibit distinct signatures associated with transient strain. We experimentally observe the arrival of strain pulses via the reflectivity change. The tr-MOKE response measured without changing the pump-probe geometry is delayed by several picoseconds. This suggests a genuine magnetization response as opposed to instantaneous changes of optical constants as the origin of the signal. We model the propagation of longitudinal acoustic picosecond strain pulses and incorporate the inverse magnetostriction effect via a magnetoelastic term in the effective field of the Landau-Lifshitz-Gilbert equation with large damping. This reproduces not only the delay of the pulsed response, but also unveils the dominant contribution of quasi-static strain to the magnetization dynamics due to the thermal expansion in the optically probed near-surface region. Our experiments exemplify that purely longitudinal strain along the out-of-plane direction of the thin film enables efficient magnetoelastic coupling via the shear strain components arising in the oblique crystallographic frame of reference.
title Large strain contribution to the laser-driven magnetization response of magnetostrictive TbFe$_{2}$
topic Materials Science
url https://arxiv.org/abs/2505.21211