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

Schematic drawing shows an electron (gold sphere) moving in the direction of the green arrow on the surface of a topological crystalline insulator. In this material, the electron’s quantum-mechanical spin (up) (blue arrow) is coupled with the direction of its motion in such a way that reversing its direction of motion would reverse the direction of the spin (down).

You Can Have Your Conductor and Insulator, Too

Scientists synthesized a theoretically-predicted material with unusual current-carrying properties that could open the door for next-generation electronics.

Ultrafast pump-probe microscopy on individual vanadium dioxide microcrystals measures the spatial and temporal variability of ultrafast dynamics of the insulator-to-metal transition.

Small Variations Mean Big Changes in Oxide’s Transformation from Insulator to Conductor

Study reveals surprising non-uniformity in vanadium dioxide that could one day enable more energy-efficient technologies.

A simple chemical analogue to a biological cell responds to a perceived threats.

Spontaneous Pressure Regulation within Artificial Cells

Simple human-made cellular analogues both sense and regulate in response to externally created stress.

A stripe-shaped magnetic region (domain), shown in blue (top left) in an ultrathin film device (orange structure). The narrowing region of the device causes the current distribution to change (two of the three red arrows change direction), leading to the breakdown of the magnetic domain into circular disk-shaped bubbles, called skyrmions (bottom left) Magnetic skyrmion bubbles (bottom right) were experimentally observed using magnetic imaging.

Creating Novel Magnetic Islands for Spintronics

Generating and moving small, stable magnetic islands at room temperature could be the ticket to more energy-efficient electronics.

The microtubules (green) pull polymer nanotube networks (red) from polymer reservoirs (fluorescence image).

Build a Network, Cellular Style

Bio-based molecular machines mechanically extrude tiny tubes and form networks, aiding in the design of self-repairing materials.

Researchers from the Molecular Foundry, working with users from Columbia University led by Latha Venkataraman, have created the world’s highest-performance single-molecule diode using a combination of gold electrodes and an ionic solution.

Viable Single-Molecule Diodes

Major milestone in molecular electronics scored by Molecular Foundry and Columbia University team.

Match-Heads Boost Photovoltaic Efficiency

Tiny “match-head” wires act as built-in light concentrators, enhancing solar cell efficiency.

Working with Molecular Foundry staff, an international team of users utilized the TEAM 1 microscope to plot the exact coordinates of nine layers of atoms with a precision of 19 trillionths of a meter.

Unprecedented Precise Determination of Three-Dimensional Atomic Positions

For the first time, electron tomography reveals the 3D coordinates of individual atoms and defects in a material.

Schematic of a “solar flow battery” with the three-electrode configuration: lithium anode electrode, counter electrode (CE), and photo-electrode (PE).

Eco-friendly Battery and Solar Cell All-in-One

Keeping the lights on: Solving the intermittency shortcomings of renewable solar energy.

Picture of newly-devised frequency comb.

Toward Powerful and Compact Terahertz Spectrometers

A new, dime-sized light source will lead to novel spectrometers for the next generation of scientific discoveries.

Visualized model of a superlubricity (low-friction) system: gold = nanodiamond particles; red = graphene nanoscroll; green = underlying graphene on silica; black = diamond-like carbon surface.

Near Zero Friction from Nanoscale Lubricants

Researchers have attained superlubricity, the near absence of friction, at a carbon-silica interface using nanodiamonds wrapped in graphene flakes.

A Nobel for Neutrinos: Sudbury Neutrino Observatory

Discovery of neutrino oscillations, which shows that neutrinos have mass, garners the 2015 Nobel Prize in Physics.