SUF 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.

Problem Turned Into Performance for Solar Cells

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

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.

A scanning probe microscope (SPM) can detect two similar signals, which could lead to ambiguous identification of ferroelectric materials.

Ferroelectricity – Ambiguity Clarified, and Resolved

Novel technique accurately distinguishes rare material property linked to improving sensors and computers.

Advanced electron microscopy technique permits the simultaneous collection of both signals: secondary electron (that are sensitive to the surface) and transmitted electron.

Atomic-Level Measurements of Rough Surfaces

Researchers use surface-sensitive signals to atomically resolve the structure of a rough surface.

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.

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.

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.

Fan-cooled heat sink on a microprocessor.

Hundred-Fold Improvement in Temperature Mapping Reveals the Stresses Inside Tiny Transistors

New nanoscale thermal imaging technique shows heat building up inside microprocessors, providing new information to help solve heat-related performance issues.

Formation of large-scale 3D binary crystals with predictable lattice symmetry, as determined by the cubic geometry and DNA-encoded interactions between cubes and spheres (scale bar: 500nm)

Nanoscale Building Blocks and DNA “Glue” Help Shape 3D Architectures

New approach to design and assemble tiny composite materials could advance energy storage.