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

This artistically enhanced depiction shows an atom being hit by a strong rosette-shaped laser field (purple), ripping an electron (green) from the parent atom that then re-collides with the atom.

Combining Electrons and Lasers to Create Designer Beams for Materials Research

Tabletop laser systems generate extreme ultraviolet probes will advance research towards a new generation of energy-conserving electronics.

A liquid metal technique drives the transformation of uniform alloys into a nanoscale mixture of two materials with different compositions.

Nano-Sculptures for Longer-Lasting Battery Electrodes

Liquid metal transforms solid alloy into pore-filled structure that could be used in future batteries.

Solar energy can be stored by using sunlight to split water (H2O) into hydrogen and oxygen.

Simple Preparation for Affordable Solar Energy Storage

Inexpensive method allows synthesis of a tiny solar cell that pumps out fuel.

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.

Materials used for their mechanical strength employ a variety of toughening mechanisms.

Can We Beat Mother Nature at Materials Design?

Scientists review how we are matching – or exceeding – nature’s ability to make strong, tough lightweight structural materials.

A versatile two-step process allows for the controlled synthesis of new materials for energy technology.

New Approach to Room-Temperature Materials Synthesis - Low Cost, Simple, and Controlled Composition

Templates allow for materials with deliberate sizes and shapes for solar cells and electricity generation from waste heat.

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.

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.

A snapshot from a large quantum molecular dynamics simulation of the production of hydrogen molecules (green) from an aluminum-lithium alloy nanoparticle containing 16,661 atoms (represented by the silver contour of charge density) and dissolved charged lithium atoms (red).

Towards Eco-friendly Industrial-Scale Hydrogen Production

Atomic-scale simulations predict how to use nanoparticles to increase hydrogen production.

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.

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.

The cross-section shows key features of a new solar cell architecture.

Keep it Simple: Low-Cost Solar Power

A simplified architecture leads to efficiencies rivaling conventional silicon solar cells.