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 »
This Exotic Particle Had an Out-of-Body Experience; These Scientists Took a Picture of It
Scientists have taken the clearest picture yet of electronic particles that make up a mysterious magnetic state called a quantum spin liquid (QSL), in which electrons decompose into spin-like particles (spinons) and charge-like particles (chargons). The achievement could facilitate the development of superfast quantum computers and energy-efficient superconductors. Read more »
Main Attraction: Scientists Create World’s Thinnest Magnet
A one-atom-thin 2D magnet that operates at room temperature could lead to new applications in computing and electronics—such as high-density, compact spintronic memory devices—and new tools for the study of quantum physics. X-ray experiments at the ALS characterized the material’s magnetic parameters under high temperature. Read more »
Tuning Semimetallicity Using Thin Films and Interfaces
With support from ALS data, scientists gained new insight into a semimetal’s unusual electronic behavior. The work lays out a basic strategy for engineering the band structures of semimetallic compounds using dimensional confinement and reveals a new way of creating two-dimensional electron/hole gases by exploiting interfacial bonding. Read more »
Label-Free Characterization of Organic Nanocarriers
A technique developed at the ALS enables accurate characterization of organic nanocarriers (molecules that encapsulate other molecules) without the need for disruptive labeling. The method will enable faster, more precise development of exciting new technologies, ranging from targeted drug delivery to oil-spill remediation. Read more »
Scientists Uncover a Different Facet of Fuel-Cell Chemistry
Solid oxide fuel cells are a promising technology for cleanly converting chemical energy to electrical energy. To improve the efficiency of these devices, researchers studied a model electrode material in a new way—by exposing a different facet of its crystal structure to oxygen gas at operating pressures and temperatures. Read more »
Artificial Spin Ice Toggles Twist in X-Ray Beams on Demand
ALS studies helped scientists understand how a nanoscale magnetic lattice (an artificial spin ice) acts as a toggle switch for x-ray beams with spiral character. The findings represent an important step toward the development of a versatile new tool for probing or controlling exotic phenomena in electronic and magnetic systems. Read more »
Single-Domain Multiferroic Array-Addressable Terfenol-D (SMArT) Micromagnets for Programmable Single-Cell Capture and Release
Researchers develop programmable multiferroic micromotors that enable single-cell manipulation based on time-dependent functions of individual cells, such as cell secretion. Smart programmable multiferroic materials lay the groundwork for large-scale automated single-cell sorting and enable a broad spectrum of biotechnology applications. Read more »
Programmable Micromagnets for Single-Cell Sorting
Researchers demonstrated that electrically induced mechanical strain can control the magnetic state of tiny magnets used to sort biological cells. The work lays the foundation for a programmable, single-cell sorting platform to support a wide variety of biotechnology applications, including personalized cancer treatments. Read more »
Graphene Outperforms Metal Junctions for 2D Semiconductors
Researchers found that graphene performs ten times better than metal in transmitting a photoinduced current across interfaces with 2D semiconductors. Nanoscale-resolution band-structure measurements provided a deeper understanding of charge transport in these systems and will help in engineering more efficient contacts. Read more »
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