Electrode engineering produces unprecedented selectivity, and high rates of carbon dioxide reduction to multicarbon products.
Electrode engineering produces unprecedented selectivity, and high rates of carbon dioxide reduction to multicarbon products.
Students and faculty at Cornell and North Carolina A&T are partnering on an ambitious research project.
Combining synthesis, characterization, and theory confirmed the exotic properties and structure of a new intrinsic ferromagnetic topological material.
Scientists develop a new learning method that incorporates quantum chemistry descriptions with conventional machine learning to predict the properties of biochemical molecules.
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.
New optics-on-a-chip device paves the way to helping characterize fast chemical, material, and biological processes.
At Lawrence Livermore National Laboratory, researchers simulate ion transport for ways to predict and improve materials for energy storage.
Neutron scattering monitors structures during post-production heat treatment to validate production models.
Unusual filling of different sub-shells due to quantum confinement leads to a stable superatom that is also highly magnetic.