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.
Data derived from these instruments will support climate model simulations of cloud processes.
Understanding differences in modeling soil water will help scientists simulate how this moisture affects the climate.
Mass spectrometry and high-performance computing combined, allowing scientists to study proteins that link internal processes to community attributes.
First atomically thin, halide perovskite sheets could be an alternative to graphene for future electronics.
Microporous polymer separator prevents specific molecules from crossing battery and causing degradation and shorter lifetimes.
Novel self-assembly can tune the electronic properties of graphene, possibly opening doors for tiny, powerful electronic devices.
Scientists transformed flexible one-dimensional molecular chains into a structured, well-defined porous three-dimensional material.
Predicting nanosystems with unanticipated properties can advance next-generation solar panels and electronics.
