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

Selective etching of palladium (blue) from palladium-platinum core-shell nanoparticles (left) yields hollow platinum (grey) nanocages with high activity for the oxygen reduction reaction.

Hollow and Filled with Potential

Hollow shape-selected platinum nanocages represent a new class of highly active catalysts.

This results demonstrate a temporal resolution sufficient to directly image chemical reactions.

Capturing Molecular Motion with Relativistic Electrons

The world’s fastest images of nitrogen molecules rotating in a gas were captured using electron diffraction.

Researchers discovered how green fluorescent proteins (center) react with water (shown around the edges of the protein).

New Insight on a Familiar Glow

A new approach to investigating green fluorescent protein provides a vital tool for unraveling molecular-level details of processes important in biology and light harvesting for energy use.

Energy filtered image of CoFe2C rods showing the carbon elemental map (left). Theoretical image of the CoFe2C structure showing the frontier molecular orbitals (right).

Small and Powerful: Pushing the Boundaries of Nano-Magnets

Newly discovered particles behave as powerful magnets that, one day, could change data storage.

Scanning electron microscopy image of the hair coating of Saharan silver ants, which shows the triangular cross section of the hairs.

Silver Ants Stay Cool in the Saharan Heat

Findings could lead to biomimetic coatings for passive radiative cooling technologies for buildings and vehicles.

Don’t Touch: How Scientists Study the Reactions inside Stars

Indirect method let scientists determine stellar reaction rates, providing detailed information about the universe.

What Is the Size of the Atomic Nucleus?

The neutron skin of the nucleus calcium-48 is much thinner than previously thought.

Biofuel Tech Straight from the Farm

Herbivore digestion involves a large variety of enzymes that break woody plants into biofuel building blocks.

Whether a solid or liquid forms from charged polymers depends on the “handedness” of the oppositely charged polymer chains.

Will It Be a Solid or a Liquid? The Molecular Structure Has the Answer

Oppositely charged polymer chains can be “right-handed,” “left-handed,” or have no “handedness” at all, which controls whether a solid or liquid forms.