Inner Workings of Atomically Thin Transistors
Scientists reveal conductive edges and thread-like flaws using a specialized imaging technique of interest for next-generation electronics.
Scientists reveal conductive edges and thread-like flaws using a specialized imaging technique of interest for next-generation electronics.
Analyses reveal diversity in carbon turnover and other degradation processes, offering insights for biofuel production.
Scientists explain diverse results around a material that is both insulator and conductor and offer chemical roadmap to harness it.
A simple chemical bonding approach enables assembly of very thin porous protein crystals that are bendable and adaptive—requirements for flexible electronics or batteries.
Towards higher energy density batteries: singly charged lithium ions replaced by doubly charged magnesium ions.
Sticky molecules hop aboard oily floaters and may influence the amount of sunlight reflected by marine clouds.
Researchers tackle a grand challenge by capturing vibrations in the “magic” cage formed when 21-water molecules capture a single proton.
Visible lasers offer exquisite control of x-ray light in a tabletop apparatus, potentially providing access to new insights to chemical reactions, proteins, and even atoms’ inner workings.
Previously unobserved scattering shows unexpected sensitivity to bound electrons, providing new insights into x-ray interactions with matter and opening the door to new probes of matter.
Scientists discover a direct electron-transfer process with a higher efficiency for charge separation than previous mechanisms.
Scientists discover another design principle for building nanostructures.
Team’s approach enables a highly sensitive search for a neutron electric dipole moment, which provides insights into the nature of the universe.