Topological Magnetism Group

Magnetization dynamics in ordered spin structures revealed by diffractive and reflectometry ferromagnetic resonance

AIP Advances American Institute of Physics 11:1 (2021) 15327

Authors:

Dm Burn, Shilei Zhang, G van der Laan, T Hesjedal

Abstract:

Synchrotron radiation based techniques provide unique insight into both the element and time resolved magnetization behavior in magnetic spin systems. Here, we highlight the power of two recent developments, utilizing x-ray scattering techniques to reveal the precessional magnetization dynamics of ordered spin structures in the GHz regime, both in diffraction and reflection configurations. Our recently developed diffraction and reflectometry ferromagnetic resonance (DFMR and RFMR) techniques provide novel ways to explore the dynamics of modern magnetic materials, thereby opening up new pathways for the development of spintronic devices. In this paper we provide an overview of these techniques, and discuss the new understanding they provide into the magnetization dynamics in the chiral magnetic structure in Y-type hexaferrite and the depth dependence to the magnetization dynamics in a [CoFeB/MgO/Ta]4 multilayer.

Depth profiling of 3D skyrmion lattices in a chiral magnet: A story with a twist

AIP Advances AIP Publishing 11:1 (2021) 015108

Authors:

G van der Laan, Shilei Zhang, Thorsten Hesjedal

Abstract:

From the perspective of surface science, only the topmost atomic layers usually exhibit physical properties that are different to those of the bulk material, whereas the deeper layers are assumed to be bulk-like and remain largely unexplored. Going beyond conventional diffraction and imaging techniques, we have determined the depth dependence of the full 3D spin structure of magnetic skyrmions below the surface of a bulk Cu2OSeO3 sample using the polarization dependence of resonant elastic x-ray scattering (REXS). While the bulk spin configuration showed the anticipated Bloch type structure, it was found that the skyrmion lattice changes to a Néel twisting (i.e., with a different helicity angle) at the surface within a distance of several hundred nm. The exact surface helicity angle and penetration length of this twist have been determined, revealing the detailed internal structure of the skyrmion tube. It was found that the experimental penetration length of the Néel twisting is 7× longer than the theoretical value given by the ratio of J/D. This indicates that apart from the considered spin interactions, i.e., the Heisenberg exchange interaction J and the Dzyaloshinskii-Moriya interaction D, as well as the Zeeman interaction, other effects must play an important role. The findings suggest that the surface reconstruction of the skyrmion lattice is a universal phenomenon, stemming from the breaking of translational symmetry at the interface.

Creation of a Chiral Bobber Lattice in Helimagnet-Multilayer Heterostructures

PHYSICAL REVIEW LETTERS 126:1 (2021) ARTN 017204

Authors:

Kejing Ran, Yizhou Liu, Yao Guang, David M Burn, Gerrit van der Laan, Thorsten Hesjedal, Haifeng Du, Guoqiang Yu, Shilei Zhang

Creation of a Chiral Bobber Lattice in Helimagnet-Multilayer Heterostructures

(2020)

Authors:

Kejing Ran, Yizhou Liu, Yao Guang, David M Burn, Gerrit van der Laan, Thorsten Hesjedal, Haifeng Du, Guoqiang Yu, Shilei Zhang

Optically and microwave-induced magnetization precession in [Co/Pt]/NiFe exchange springs

ACS Applied Materials and Interfaces American Chemical Society 12:46 (2020) 52116-52124

Authors:

Maciej Dabrowski,, Andreas Frisk, David Burn, David Newman, Christoph Klewe, Alpha N'Diaye, Padraic Shafer, Elke Arenholz, Graham Bowden, Thorsten Hesjedal, Gerrit van der Laan, Gino Hrkac, Robert Hicken

Abstract:

Microwave and heat assisted magnetic recording are two competing technologies that have greatly increased the capacity of hard disk drives. The efficiency of the magnetic recording process can be further improved by employing non-collinear spin structures that combine perpendicular and in-plane magnetic anisotropy. Here, we investigate both microwave and optically excited magnetization dynamics in [Co/Pt]/NiFe exchange spring samples. The resulting canted magnetization within the nanoscale [Co/Pt]/NiFe interfacial region allows for optically stimulated magnetization precession to be observed for an extended magnetic field and frequency range. The results can be explained by formation of an imprinted domain structure, which locks the magnetization orientation and makes the structures more robust against external perturbations. Tuning the canted interfacial domain structure may provide greater control of optically excited magnetization reversal and optically generated spin currents, which are of paramount importance for future ultrafast magnetic recording and spintronic applications.