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

Hot nanowires emit lattice vibrations known as phonons into underlying materials. When closely packed, phonon collisions can more efficiently transport heat away.

Staying Close and Keeping Cool

Hot nanostructures cool faster when they are physically close together.

Most Complete Functional Map of an Entire Enzyme Family

Researchers develop a new process for annotating cellulose-degrading enzymes.

The new patent includes a compact programmable NANOrotator that allows the fabrication of “smart” tips.

Chemical Fingerprinting of Materials Takes More Than Just a Dab of Ink

Researchers patent new x-ray microscopy technology to “see” both the chemical and physical aspects of materials.

Complete nanobatteries are formed in each nanopore of a dense nanopore array (2 billion per square centimeter).

Precision Nanobatteries by the Billions

Tiny batteries made in nanopores manage ions and electrons for high power and extended life.

Rendering of carbon nanothreads as suggested by characterization techniques.

Carbon Nanothreads from Compressed Benzene

One-dimensional material has a diamond-like building block.

Map of carbon dioxide dissolution across the Bravo Dome gas field.

Carbon Sequestration in New Mexico’s Bravo Dome

Study of natural reservoir provides new clues for the long-term viability of geological carbon dioxide storage.

Numerical simulation of the magnetic inhomogeneity (red = magnetism, blue = superconductivity) caused by replacing 1% of the indium atoms in a superconductor (CeCoIn5) with cadmium atoms.

A potential Rosetta Stone of high temperature superconductivity

Discovery paves the way to quantitatively investigate the interplay among magnetism, superconductivity and disorder in high temperature superconductors.

Depiction of carbon nanotube (gray) inserted into a cell membrane, with a single strand of DNA (gold) passing through the nanotube.

Spontaneous Formation of Biomimetic, Nanoporous Membrane Channels

Carbon nanotubes insert into artificial and active cell membranes, reproducing major features of biological channels.

Palladium-nickel nanoparticles (top structural model) are synthesized and then exposed to reactive gases (lower right) while being probed with high-energy x-rays.

Optimizing Atomic Neighborhoods for Speedier Chemical Reactions

Clusters with longer separations between atoms had enhanced catalytic activity.

Illustration of the catalytic oxygen reduction reaction on the surface of platinum-nickel nanoframes with multilayered platinum skin structure

Multimetal Nanoframes Improve Catalyst Performance

Concentrating noble-metal catalyst atoms on the surface of porous nano-frame alloys shows over thirty-fold increase in performance.

Changes in the crystal structure and electronic properties of vanadium dioxide (VO2) occur during its insulator-to-metal phase transition (V blue; O red)

Insulator-to-Metal Transition of Vanadium Dioxide

New studies explain the transition, providing a quantitative picture of a 50-year-old mystery.

The magnetic coercivity, the resistance to change in the orientation of the magnetic domain structure, for nickel (Ni) was shown to strongly depend on the crystal structure of the underlying oxide (vanadium oxide, V2O3).

Giant Magnetic Effects Induced in Hybrid Materials

Magnetic property changes by several hundred percent over a narrow temperature range.