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

Modeling Sunlight Harvesting in Nanostructures

Predicting nanosystems with unanticipated properties can advance next-generation solar panels and electronics.

Soft and Small Imaging Breakthrough

Researchers develop breakthrough technique for non-invasive electron microscopy for soft materials

Water Gunks Up Biofuels Production from Bio-Oils

New findings will help extend the lifetime of catalysts used to process bio-oils in liquid systems.

A new algorithm reduces timing uncertainty by a factor of 300, revealing ultrafast dynamics on timescales as short as a quadrillionth of a second.

Creating a Better Way to Find Out “When”

Computer algorithm recovers histories and dynamics on timescales much faster than uncertainties inherent in experimental data.

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.

The orange carotenoid protein of cyanobacteria binds a single carotenoid pigment molecule that may dissipate excess light energy when it moves within the protein.

Changing Colors for Built-in Sunblock

Molecular movements triggered by light redirect the flow of energy through photosynthetic cells to protect them from sun damage.

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.

Adding a water molecule to the positively charged protactinium dioxide ion results in hydrolysis, or water splitting.

Rare Meets Common: Reacting Protactinium with Ubiquitous Water Explains an Elemental Oddity

Reactions with this extremely rare element could reveal previously unknown trends, benefiting studies of new nuclear reactor fuels.

Solar Water Splitting: Putting an Extra “Eye” on Surface Reactions that Store Sunlight as Fuel

A novel technique allows new insight into the barriers to fuel evolution.

The newly-proposed structure of ceric ammonium nitrate, with an oxygen bridge, may explain why this popular industrial reagent is so versatile.

What CAN It Be?

Elucidating Cerium Solution Chemistry