Science Highlights | U.S. DOE Office of Science (SC)

Depiction of superionic phase of copper (blue) diffusing through the sulfur (yellow) sublattice.

Watching Ions Hop in Next Generation Battery Materials

Atomic-Scale, femtosecond time-scale measurements unravel the atomistic pathways and speed limits for copper migration through a nanocrystal.

Schematic figure of solid-electrolyte interphase (SEI) layer formed during the first charging cycle illustrating a interphase layer comprised predominantly of a mixture of lithiumethylene dicarbonate (LEDC) and lithium fluoride (LiF).

Revealing the Illusive Interphase in Lithium Ion Batteries

Structure and composition of the Solid Electrolyte Interphase in lithium ion batteries was investigated via a unique combination of microscopy and spectroscopy.

Inelastic neutron scattering of high-quality single-crystal samples of the mineral ZnCu3(OD)6Cl2.

Experimental Confirmation of a New State of Magnetism Previously Predicted by Theory

This observation paves the way for a deeper understanding of high-temperature superconductivity and future applications for quantum computing.

With increasing hydration within the interlayer space of the initially disordered lipid membranes, lateral layer-by-layer phase separation begins.

The Medium Matters

Long-range, three-dimensional alignment and stacking of multiple regions within biologically derived membranes.

The composition of solvents, such as chloroform and toluene, during nanoparticle fabrication can alter the internal aggregate structure of polymer P3HT...

Bridging the Nano-World and the Real World in Polymer Solar Cells

Discovering how polymer organization on the molecular level affects electric charge movement in organic solar cells.

Spatially resolved activation energy map overlaid with sample topography

Catching Lithium Ions in Action in a Battery Electrode

New microscopy with nanometer-sized resolution may bring revolutionary new understanding to energy storage technologies.

Schematic representation of the atomic lattice of Tellurium-Antimony (Sb)-Germanium (Ge)-Silver (Ag) thermoelectric doped with rare earth dysprosium (Dy).

Rare Earth Atoms Make the Best Thermoelectrics Better

Small addition of rare earth element makes a big difference in converting heat to electricity.

Diamond anvil showing dents (arrowed) after being used to squeeze this new superhard material.

New Superhard Form of Carbon Dents Diamond

Squeezing creates new class of material built from clusters of carbon atoms.

Oxygen vacancy maps reveal that the overall composition and the degree of oxygen order varies drastically between films of the same cation composition but grown on different substrates.

Seeing the Voids in Fuel Cell Materials at the Atomic Scale

New microscopy method opens the door to understanding atomic-scale variations in chemistry and improved materials performance in solid oxide fuel cells.