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

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.

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.

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

The benchmark catalyst Fe(CO)5 is irradiated with ultraviolet light, causing it to lose one of its five carbon monoxide groups.

Scientists Track Ultrafast Formation of Catalyst with X-ray Laser

First-of-its-kind measurements provide insights on reactions that could one day turn sunlight and water into fuels.

A Super Uranyl-binding Protein with high affinity and selectivity could be used to mine uranium from seawater in the future.

Skimming Uranium from the Sea

Using computational methods, scientists tailor and adapt proteins to mine uranium from seawater.

The matrix-free ionization platform consists of an array of silicon nanoposts.

One in a Million: Analyzing Metabolites in a Single Cell

Commercialized nanopost array platform reveals metabolic changes in individual cells due to environmental stress.

A novel catalyst transforms carbon dioxide and hydrogen into formic acid (HCOOH) via a two-step (yellow arrows) reaction.

Capturing and Converting CO₂ in a Single Step

Researchers computationally design a cheap, efficient catalyst that captures carbon dioxide and creates a chemical building block.

Understanding the conditions and pathways that position populations of isolated ions and shared proton species as they react in water allows scientists to better understand the chemistry of concentrated hydrogen chloride solutions, which has implications in chemical processes ranging from refining oil to building longer-lasting batteries

Keeping the Ions Close: A New Activity

Study changes perception on how acids behave in water.

Scientists reported the first direct detection of a hydroperoxyalkyl radical—a class of reactive molecules denoted “QOOH”—that are key intermediates in combustion and atmospheric chemistry.

Combustion’s Mysterious “QOOH” Radicals Exposed

Direct measurement of an elusive but critical combustion molecule leads to more accurate models of ignition chemistry.