
The Building Blocks for Exploring New Exotic States of Matter
Combining synthesis, characterization, and theory confirmed the exotic properties and structure of a new intrinsic ferromagnetic topological material.
Combining synthesis, characterization, and theory confirmed the exotic properties and structure of a new intrinsic ferromagnetic topological material.
Neutrons reveal remarkable atomic behavior in thermoelectric materials for more efficient conversion of heat into electricity.
Studies of the nanostructure of a chiral magnet provides insights on controlling magnetic properties for applications in computers and other electronics.
State-of-the-art X-ray techniques found hidden damage in neutron irradiated silicon carbide, a possible structural material for future fusion reactors.
Designer polymers effectively mimic natural proteins in proton transport across membranes for health and energy technologies.
Researchers have created a novel membrane platform for studying the structure and function of membrane proteins in their realistic environment.
Neutron and X-ray scattering shed light on exotic states that determine the electronic properties of materials.
Neutron scattering and isotopic substitution techniques reveal how to block vibrations that could leak heat from a photovoltaic cell.
Neutron and X-ray experiments illuminate the magnetic transitions in hexagonal iron sulfide that transform it from a conductor to an insulator.
Collaboration between experiment and theory expands fundamental understanding of the chemistry of exotic radioactive heavy elements.
A test of titanium diboride opens the door to a potential new class of materials for fusion reactor applications.
Production of actinium-227 ramps up for use in a drug to fight prostate cancer that has spread to bone.