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

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.

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.

Specially designed, extremely small metal structures can trap light.

Light Speed Ahead!

Surface plasmons move at nearly the speed of light and travel farther than expected, possibly leading to faster electronic circuits.

When gaseous carbon dioxide (center) is dissolved in water, its water-fearing or hydrophobic nature creates a cylindrical cavity in the liquid, setting the stage for the proton transfer reactions that produce carbonic acid

The Importance of Hydration

Spectroscopy combined with theory and computation determines the interaction between carbon dioxide and water.

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.

Fan-cooled heat sink on a microprocessor.

Hundred-Fold Improvement in Temperature Mapping Reveals the Stresses Inside Tiny Transistors

New nanoscale thermal imaging technique shows heat building up inside microprocessors, providing new information to help solve heat-related performance issues.

Formation of large-scale 3D binary crystals with predictable lattice symmetry, as determined by the cubic geometry and DNA-encoded interactions between cubes and spheres (scale bar: 500nm)

Nanoscale Building Blocks and DNA “Glue” Help Shape 3D Architectures

New approach to design and assemble tiny composite materials could advance energy storage.

To help identify routes to mitigate toxic polycyclic aromatic hydrocarbons and soot formation from combustion engines, scientists identified the full list of products in a key reaction between phenyl radicals and oxygen.

Up in Flames: Phenyl Oxidation Product Distribution

Researchers determine the reaction pathway to how soot and other toxic components form in combustion systems.

The top figure shows the energy/time distribution of the twin bunches measured with an X-band transverse deflector.

Two-color X-rays Give Scientists 3-D View of the Unknown

Pairs of precisely tuned X-ray pulses uncover ultrafast processes and previously unmapped structures.

High-speed photographs of a falling water droplet on a nanostructured surface (top) before, (middle) during, and (bottom) after impact.

Super Water-Repellant Coatings Can Now Take the Pressure

Careful tuning of a surface at the nanoscale could lead to robust materials for solar panels, other uses.

Atomic structure of the adsorbed carbon dioxide (grey sphere bonded to two red spheres) inserted between the manganese (green sphere) and amine (blue sphere) groups within the novel metal-organic framework, forming a linear chain of ammonium carbamate (top)

Cooperative Carbon Capture by a Novel Material that Mimics a Plant Enzyme

Innovative materials adsorb carbon dioxide via an unprecedented cooperative insertion mechanism.