Communications Physics (Mar 2024)

Controlling effective field contributions to laser-induced magnetization precession by heterostructure design

  • Jasmin Jarecki,
  • Maximilian Mattern,
  • Fried-Conrad Weber,
  • Jan-Etienne Pudell,
  • Xi-Guang Wang,
  • Juan-Carlos Rojas Sánchez,
  • Michel Hehn,
  • Alexander von Reppert,
  • Matias Bargheer

DOI
https://doi.org/10.1038/s42005-024-01602-z
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 10

Abstract

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Abstract Nanoscale heterostructure design can control laser-induced heat dissipation and strain propagation, as well as their efficiency for driving magnetization precession. Here, we incorporate MgO layers into the experimental platform of metallic Pt-Cu-Ni heterostructures to block the propagation of hot electrons. We show via ultrafast x-ray diffraction the capability of our platform to control the spatio-temporal shape of the transient heat and strain. Time-resolved magneto-optical Kerr experiments with systematic tuning of the magnetization precession frequency showcase control of the magnetization dynamics in the Ni layer. Our experimental analysis highlights the role of quasi-static strain as a driver of precession when the magnetic material is rapidly heated via electrons. The effective magnetic field change originating from demagnetization partially compensates the change induced by quasi-static strain. The strain pulses can be shaped via the nanoscale heterostructure design to efficiently drive the precession, paving the way for opto-magneto-acoustic devices with low heat energy deposited in the magnetic layer.