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Dynamic Measurements of Antiferromagnetically Aligned Spins

Researchers developed a technique that enables time-resolved, direct detection of spin currents in either ferromagnetic or antiferromagnetic materials at GHz frequencies. Studying the dynamic properties of antiferromagnetic spintronic effects could lead to greater stability and faster intrinsic switching speeds compared to conventional spintronics. Read more »

A Novel Insulating State Emerges in a 2D Material

Researchers found a unique insulating state in an atomically thin material, driven by the combined effects of lattice–charge interactions and atomic-bond formation. The work provides a better understanding of charge ordering in two-dimensional materials and opens up new possibilities for achieving designer electronic properties. Read more »PPT-icon-35 PDF-icon-35

What Drives Electron–Hole Asymmetry in Graphene?

Using the ALS, researchers determined that interactions between electrons are what give rise to the divergent effects observed when graphene is doped with electrons versus holes. A better understanding of this electron–hole asymmetry could lead to new avenues for generating exotic material phases, including unconventional superconductivity. Read more »PPT-icon-35 PDF-icon-35

New Device Advances Commercial Viability of Solar Fuels

A Berkeley Lab research team developed a new artificial photosynthesis device component that exhibits remarkable stability and longevity as it selectively converts sunlight and carbon dioxide into two promising sources of renewable fuels—ethylene and hydrogen. Read more »

Interface Sensitivity in Electron/Ion Yield X-ray Absorption Spectroscopy: The TiO2–H2O Interface

To understand corrosion, energy storage, (electro)catalysis, etc., obtaining chemical information on the solid–liquid interface is crucial but remains extremely challenging. Here, x-ray absorption spectroscopy is used to study the solid–liquid interface between TiO2 and H2O. This result highlights the potential of electron-yield XAS to obtain chemical and structural information with a high sensitivity for the species at the electrode–electrolyte interface. Read more »

3D View Reveals Shadow Effect after Rapid Battery Charging

Using 3D x-ray microtomography, researchers measured the lithiation levels of particles in Li-ion battery electrodes during charging. At faster charging rates, lithium metal accumulated on the electrode surface and created a “shadow effect,” a region of poor lithiation in the electrode at some distance away from the lithium plating. Read more »

A Two-Dimensional Room-Temperature Magnet

Researchers have made the world’s thinnest (one atom thick) magnet that’s chemically stable under ambient conditions. The two-dimensional material, magnetically characterized at the ALS, could enable big advances in next-generation memory devices, computing, spintronics, and quantum physics. Read more »PPT-icon-35 PDF-icon-35

Exquisitely Selective CO2 Reduction on Silver

Researchers electrochemically reduced CO2 to CO with nearly perfect selectivity over other products by adding an organic compound to the surface of a silver electrode. With theoretical analyses and ALS data, the work revealed the key role of the microenvironment in promoting the conversion of CO2, a greenhouse gas, into useful products. Read more »PPT-icon-35 PDF-icon-35

A Powerful Infrared Technique Broadens Its Horizons

Scattering-type scanning near-field optical microscopy (s-SNOM) focuses infrared light to dimensions below the diffraction limit, measuring properties with components perpendicular to the sample surface. Researchers have now devised a way to probe components parallel to the sample, where the technique has been less sensitive. Read more »