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

This tabletop laser system allows for unprecedented characterization of superconductors, semiconductors, and other electronic materials by increasing the energy of an infrared laser to the sought-after extreme ultraviolet, which is invisible.

Bridge to Coveted Electronic Properties

New tabletop laser achieves sought-after energies needed for advanced characterization with unprecedented precision and range.

Absorption of sunlight in silicon solar cells results in losses due to heat from “hot” photo-excited electrons.

Taking on the Heat in Solar Cells: New Calculations Show Atomic Vibrations Hurt Efficiency

Theoretical modeling of energy loss in solar cells may lead to more efficient materials to convert sunlight to electricity.

Tuning topology and adhesion of metal nanomeshes has led to super stretchable, transparent electrodes that don’t wear out.

Nano-stiltskin: Turning Gold into … See-through Rubber

New metal nanomesh leads to super stretchable and transparent gold electrodes that don’t wear out.

The schematic shows protected edges that allow the propagation of these magnetic waves in a single direction along the edge of the crystal.

Surf’s Up: Magnetic Waves on the Edge

First realization of a novel material that can conduct magnetic waves on its edge, but not within its bulk.

A cage-like protein (gray) called ferritin was engineered to have metal hubs (blue) on its surface.

Modular Construction - on a Molecular Scale

Predictable assembly of protein building blocks result in a new class of porous materials, with potential uses ranging from efficient fuel storage to practical carbon capture and conversion.

Films integrated into the cell created an efficient solar-to-hydrogen cell using Earth-abundant cobalt rather than rare and expensive metals.

Hydrogen Production from a Relative of Fool’s Gold

Affordable, Earth-abundant catalyst achieves efficient solar-driven hydrogen fuel production.

Electrons have distinct energy levels where the energy is minimized, similar to a ball rolling down a mountain to a valley.

Laser Manipulates Electronic Properties

Dressing electrons with a rotating field of laser light creates distinct, controllable states, opening the door for innovative electronics.

The atomic force microscopy image of the junction between the graphene domains shows an electron-deficient region.

This Message Will Self-Destruct

New electron-beam writing technique controls electronic properties for future on-demand re-configurable electronics.

Two-dimensional snapshot used to reconstruct the 3D image of a particle.

Saturday Night at the Movies: 3D Sneak Preview of Dancing Platinum Particles at Atomic Resolution

Three-dimensional structure of nanocrystals in solution determined with atomic resolution using a new technique.

When light is absorbed by solar cells to make electricity, electrons and “missing electrons” are generated that move through the layers of materials in typical solar cells.

New See-Through Material for Electronics

A low-cost, stable oxide film is highly conductive and transparent, rivaling its predecessors.

Perovskite-based nanowire lasers are the most efficient known.

World’s Most Efficient Nanowire Lasers

Materials with extraordinary performance in solar cells are discovered to be efficient, tunable lasers at room temperature.

Progressively magnified images of graphene nanoribbons grown on germanium semiconductor wafers.

Growing Graphene Ribbons in One Direction

New method to fabricate graphene nanoribbon arrays on semiconductor wafers turns semimetal into semiconductor.