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

The deposition of a silicon dioxide layer (yellow layer) on a carbon nanotube (gray spheres) introduces solitary oxygen dopants (red spheres).

Using Nanotubes to Create Single Photons for Quantum Communication

Demonstration of room temperature, single photon emission in doped carbon nanotubes opens a new path toward quantum information technologies.

Nanostructured sheets created using microwaves are envisioned here on an electrode surface for the hydrogen evolution reaction (green circles are molybdenum atoms, yellow circles are sulfur atoms).

New Microwave Synthesis Technique Produces More - Affordable Hydrogen

Scientists synthesize what could be a low-cost, earth-abundant material that splits water to make hydrogen fuel.

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.

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.

Moth eyes are highly antireflective due to their nanostructured surface.

Artificial Moth Eyes Enhance Silicon Solar Cells

A novel approach to design and assembly of nanotextured surfaces on photovoltaic devices could improve energy collection.

Problem Turned Into Performance for Solar Cells

Boundaries between crystalline grains - usually detrimental - can also boost charge collection in hybrid solar cells.

Short laser pulses (the wide red arrow) on the order of femtoseconds (one quadrillionth of a second) changed the electronic properties of a material (the brown hexagonal shape) by triggering phase transitions.

Lasers Leave a Mark on Materials - At the Atomic Level

Ultrafast laser shots act like dopants to create new electronic properties in materials.

Artist conception highlights electron behavior in a single layer of iron-selenium atoms (red and purple) on a strontium titanate layer (blue pyramid shapes).

Vibrations Raise the Critical Temperature for Superconductivity

Scientists reveal that coupling between electrons and atomic vibrations play a key role in this vexing phenomenon.

Aluminum-ion batteries could rapidly charge - in less than one minute.

A Step Towards New, Faster-Charging, and Safer Batteries

First prototypes of aluminum-ion batteries charge quickly and have the potential for long lifetimes, low cost, and safe operation.

Defects (red and blue markings) surprisingly self-organize in active liquid crystal film of protein filaments and such dynamic reorganization could lead to new approaches for designing self-healing materials.

Defects Lead to Order

Surprising order found in bundles of protein filaments that move chaotically and form liquid crystals that could led to novel self-healing.

In an iron-based superconductor, model patterns of electron spins show two competing liquid-like magnetic phases. (Positive spins correspond with yellow and red, while negative spins are green and black.)

Magnetic Dance at the Threshold of Superconductivity

Near the onset of superconductivity, continuous exchange of electrons occurs between distinct, liquid-like magnetic phases in an iron-based superconductor.

X-rays can characterize the motion of atomic-scale defects (for example, dislocations) relative to the morphology of a nanoparticle in the electrode of an operating lithium-ion battery. The dislocations are extra planes of atoms inserted into the atomic lattice.

Tracking Hidden Imperfections Inside Operating Lithium-ion Batteries

Penetrating x-rays can image defects and phase changes during battery charging and discharging.