Spintronics: X-ray microscopy unravels the nature of domain walls
Die beiden oberen Reihen zeigen den erwarteten magnetischen Bildkontrast für Skyrmionen vom Bloch- und Néel-Typ bei Verwendung von zirkular, linear horizontal (LH) und linear vertikal (LV) polarisierter Röntgenstrahlung. Die Ergebnisse der experimentellen Raster-Transmissions-Röntgenmikroskopie (STXM) sind in der unteren Reihe dargestellt, sie entsprechen der Simulation der Skyrmionen vom Néel-Typ. © HZB
Magnetic skyrmions are tiny vortices of magnetic spin textures. In principle, materials with skyrmions could be used as spintronic devices, for example as very fast and energy-efficient data storage devices. But at the moment it is still difficult to control and manipulate skyrmions at room temperature. A new study at BESSY II analyses the formation of skyrmions in ferrimagnetic thin films of dysprosium and cobalt in real time and with high spatial resolution. This is an important step towards characterising suitable materials with skyrmions more precisely in the future.
Isolated magnetic skyrmions are topologically protected spin textures that are in the focus of research interest today. Also because of their potential applications in information technology. Skyrmions of particular interest occur in ferrimagnetic rare earth-transition metal (RE-TM) materials. They exhibit tunable ferromagnetic properties with antiferromagnetically coupled sublattices. By choosing elements from the rare earth and transition metal group, they provide a playground for controlling magnetisation and perpendicular magnetic anisotropy. These are key parameters for stabilising topological ferrimagnetic textures
Determining spin structures at BESSY II
One class of ferrimagnetic alloys has a stronger perpendicular magnetic anisotropy, including a compound of dysprosium (Dy) and cobalt (Co). These materials could store information in a much more stable way. But their magnetic properties and structures have hardly been studied so far. A team led by HZB physicist Dr. Florin Radu has now analysed DyCo3 samples using X-ray microscopy methods at BESSY II and determined the spin structures.
They used scanning transmission X-ray microscopy with both X-ray magnetic circular dichroism and X-ray magnetic linear dichroism as element specific contrast mechanisms. The key feature exploited here is that the linear dichroism of RE materials is much stronger than that of the TM materials. “This allowed us to directly observe isolated ferrimagnetic skyrmions in high density and to accurately determine their domain wall type,” Radu reports. The results show that the ferrimagnetic skyrmions are of the Néel type and can be clearly distinguished from the other domain walls, the Bloch walls. Thus, for the first time, the type of domain walls can now be reliably determined by X-ray investigations. This is an important step towards the application of this interesting class of materials for real spintronic devices.
- Novel technique shines light on next-gen nanomaterials: how MXenes truly workResearchers have for the first time measured the true properties of individual MXene flakes — an exciting new nanomaterial with potential for better batteries, flexible electronics, and clean energy devices. By using a novel light-based technique called spectroscopic micro-ellipsometry, they discovered how MXenes behave at the single-flake level, revealing changes in conductivity and optical response that were previously hidden when studying only stacked layers. This breakthrough provides the fundamental knowledge and tools needed to design smarter, more efficient technologies powered by MXenes.
- Porous Radical Organic framework improves lithium-sulphur batteriesA team led by Prof. Yan Lu, HZB, and Prof. Arne Thomas, Technical University of Berlin, has developed a material that enhances the capacity and stability of lithium-sulphur batteries. The material is based on polymers that form a framework with open pores (known as radical-cationic covalent organic frameworks or COFs). Catalytically accelerated reactions take place in these pores, firmly trapping polysulphides, which would shorten the battery life. Some of the experimental analyses were conducted at the BAMline at BESSY II.
- Metallic nanocatalysts: what really happens during catalysisUsing a combination of spectromicroscopy at BESSY II and microscopic analyses at DESY's NanoLab, a team has gained new insights into the chemical behaviour of nanocatalysts during catalysis. The nanoparticles consisted of a platinum core with a rhodium shell. This configuration allows a better understanding of structural changes in, for example, rhodium-platinum catalysts for emission control. The results show that under typical catalytic conditions, some of the rhodium in the shell can diffuse into the interior of the nanoparticles. However, most of it remains on the surface and oxidises. This process is strongly dependent on the surface orientation of the nanoparticle facets.