Contrary to previous reports, it’s possible to create a rechargeable battery using magnesium ions if the electrode material is first conditioned at high temperature. With twice the charge of lithium ions, magnesium ions hold great promise as the basis for high-energy-density batteries suitable for use in electric vehicles. Read more »
ALS Work Using STXM
Scanning transmission x-ray microscopy (STXM) generates microscopic images of a thin section of specimen by raster-scanning it in a focused x-ray beam. The flux of transmitted x-rays is measured to obtain the image intensity. By holding the beam at a microscopic region of interest on the sample while the photon energy is scanned, chemically sensitive x-ray absorption spectra can be measured at that specific location (spectromicroscopy).
Clues to the Early Solar System Preserved in a Meteorite
Scientists analyzing a tiny carbon-rich pocket inside a meteorite found unexpected chemical signatures. Their findings are the first direct evidence that material from the outer solar system may have traveled inward long before planets formed, providing insight into the early solar system. Read more »
Salt in the Amazon Air Comes from Local Fungi
The abundant salt in the atmosphere above the Amazon basin has long been attributed to the Atlantic Ocean. But now, using the Advanced Light Source, scientists have found that much of it originates much more locally: fungal spores in the rainforest. Pinpointing the origin will improve climate models and understanding of rainforest ecosystems. Read more »
Meteorites Suggest Galvanic Origins for Martian Organic Carbon
Nanoscale analyses of Martian meteorites suggest that organic carbon on Mars may have been formed by electrochemical reactions between briny liquids and volcanic minerals, as might occur in a galvanic cell. The study has major implications for astrobiology and could also shed light on the reactions that led to life on the early Earth. Read more »
Hidden Flow of Lithium Ions Points Way to Better Batteries
Experiments revealed that lithium ions unexpectedly flow along the surfaces of electrode particles, boosting the growth of lithium “hot spots” that shorten battery life. The results correct decades’ worth of assumptions and will help improve battery design, potentially leading to a new generation of lithium-ion batteries. Read more »
Memristor Collaboration between ALS and Hewlett Packard Labs Propels Theory to Application
The development of an idea into a commercial product can take decades, a timeframe that allows contributions from multiple generations of scientists and requires investment in basic research. Collaborative research between the ALS and Hewlett Packard Labs has advanced the memristor, a device that can store information using little to no power. Read more »
Magnetic Skyrmions: Current‐Induced Skyrmion Generation through Morphological Thermal Transitions in Chiral Ferromagnetic Heterostructures
Magnetic skyrmions are particle‐like chiral twists of the magnetization that promise advances in spin‐based data storage and logic device applications. In this article, researchers examine current‐induced generation of skyrmions in heavy‐metal/ferromagnet multilayers and show that Joule heat pulses can drive topological transitions in magnetic textures and enable skyrmion creation on nanosecond timescales. Read more »
Miscibility–Function Relations in Organic Solar Cells: Significance of Optimal Miscibility in Relation to Percolation
In this article, Ye et al. present the determination of liquidus miscibility and its temperature dependence of organic films by scanning transmission x‐ray microscopy and outline an approach to convert liquidus miscibility to an effective Flory‐Huggins interaction parameter χ, which will pave a way to predict morphology and processing strategies of polymer solar cells. Read more »
Nanoscale Characterization of Iron and Calcium in the Alzheimer’s Brain
The amyloid plaques that accumulate in Alzheimer’s disease contain stores of iron. Using scanning transmission x-ray microscopy, researchers have characterized the iron’s chemical states in unprecedented detail. Their nanoscale analysis revealed excessive chemical reduction of the iron, which can release damaging free radicals. Read more »
From Moon Rocks to Space Dust: Berkeley Lab’s Extraterrestrial Research
Berkeley Lab has a well-storied expertise in exploring samples of extraterrestrial origin. This research—which has helped us to understand the makeup and origins of objects within and beyond our solar system—stems from long-standing core capabilities in structural and chemical analyses and measurement at the microscale and nanoscale. Read more »