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

Nanometer-sized junctions between two types of two-dimensional semiconductors could replace conventional wider three-dimensional junctions.

Patterning Smaller Junctions for Ultrathin Devices

Patterned arrays of nanometer-sized connections in two-dimensional semiconductors could enable ultrathin integrated circuits for smartphones and solar cells.

The crystallized oxide (lighter regions) spelling the word “small” was “printed” on a non-crystallized layer (darker gray) by a well-controlled beam in an electron microscope.

Atomic Sculpting with a Microscope

A new tool allows atomic 3D printing.

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.

Confined in droplets, exotic phases of liquid crystals have been simulated (left) and experimentally observed (right).

Tiny Droplets… Lead to Exotic Properties

Chameleon-like color changes are observed by confining liquid crystals within small drops.

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.

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.

The discovery that electrically conductive, hair-like filaments on the surface of Geobacter bacteria could mark a new paradigm for the employment of biological materials in nanoscale electron devices.

Bacteria Hairs Make Excellent Electrical Wires

This discovery could lead to low-cost, non-toxic, biological components for light-weight electronics.

Snakes on a plane: This atomic-resolution simulation of a peptoid nanosheet reveals a snake-like structure never seen before. The nanosheet’s layers include a water-repelling core (yellow), peptoid backbones (white), and charged sidechains (magenta and cyan). The right corner of the nanosheet’s top layer has been “removed” to show how the backbone’s alternating rotational states give the backbones a snake-like appearance (red and blue ribbons). Surrounding water molecules are red and white.

Understanding and Predicting Self-Assembly

Newly discovered “design rule” brings nature-inspired nanostructures one step closer.

A vector map of the measured deflections of an atomic-sized electron beam scanned across different polar domains in the ferroelectric bismuth ferrite. The image was recorded in about a minute by the new electron microscope pixel array detector.

New High-Capability Solid-State Electron Microscope Detector Enables Novel Studies of Materials

Device allows fast, precise measurements of electric and magnetic fields at the atomic level, providing insights into the next generation of electronic, energy production, and storage materials.

Supercomputers Predict New Turbulent Interactions in Fusion Plasmas

Cutting-edge simulations provide an explanation for a mystery over half a century old.

A new algorithm reduces timing uncertainty by a factor of 300, revealing ultrafast dynamics on timescales as short as a quadrillionth of a second.

Creating a Better Way to Find Out “When”

Computer algorithm recovers histories and dynamics on timescales much faster than uncertainties inherent in experimental data.