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

Conceptual art showing the rare earth element promethium in a vial surrounded by an organic ligand. Scientists have discovered hidden features of promethium, opening a pathway for research on other lanthanide elements.

In an Advance for Promethium Production, Researchers Get a New View of the Element’s Properties

Scientists characterize a promethium coordination complex for the first time, furthering the understanding of difficult-to-study lanthanide elements.

The image using Coherent Correlation Imaging shows the areas where the borders of magnetic domains (called domain walls) accumulate over time and thus maps the presence of pinning sites. The image field of view is 700 nanometers.

Watching Magnetic Materials Get Organized in Real Time

A revolutionary Coherent Correlation Imaging method visualizes electronic ordering in magnetic materials and opens a path to new data storage technologies.

Depiction of the dynamic atomic and nanoscale evolution of a relaxor ferroelectric following photoexcitation. Light drives ultrafast reconfigurations of the domains and rotation of the ferroelectric polarization in a few trillionths of a second.

Light Makes Special Materials Move at Ultrafast Speeds

Ultrafast electron scattering measurements reveal dynamic reconfiguration of polarization in relaxor ferroelectrics by light.

A computer that uses electronic synapses made of terminals with a top electrode (TE), dielectric layer (DL), and bottom electrode (BE) can emulate the human brain. A neural network using these synapses shows improved image recognition in an MNIST test.

Emergent Device Boosts Neuromorphic Computing

Researchers open a new avenue for future brain-inspired computer hardware.

Robotic stacking of 2D material layers on a heated substrate while applying pressure pushes out residues such as polymers from between the layers, resulting in atomically clean interfaces between layers (Bottom inset: TEM cross section of the interface).

For Layered 2D Materials, Robotics Produces Cleaner Interfaces Between Stacked Sheets

Robotic stacking of 2D layers provides the atomically clean interfaces critical for high performance assembled materials.

Visualization of a 3D assembly of DNA-guided nanoparticles and frameworks (top). Multi-element template (teal) framework of tetrahedra (bottom). Zoomed-in portion shows iron (Fe), silica, platinum (Pt), and gold (Au).

“Seeing” More Sharply into Self-Assembled Nanomaterials

Researchers leveraged advanced X-ray imaging for a nondestructive way to peer inside complex 3D nanomaterials with record resolution.

Microscope image of one of the small fragments of asteroid 162173 Ryugu studied by scientists at the Advanced Photon Source. This fragment is roughly 400 microns in diameter, or about the width of six human hairs.

Illuminating the Journey of a 4-Billion-Year-Old Asteroid

By examining tiny fragments from one of our nearest cosmic neighbors, scientists uncovered more about the history of our solar system.

3D-printed metal samples are about 4 inches wide. Printed and heat-treated samples are mounted on a pedestal and exposed to a neutron beam to analyze residual stresses, or irregularities such as cracks or voids, created during the manufacturing process.

Neutrons Help Improve 3D-Printed Superalloys for Applications in Extreme Environments

Neutron experiments revealed microscopic details about a special 3D-printed superalloy that could potentially reduce component costs.

Microtomographic 3D snapshots of complex structure of thermal cracks and air bubbles in an additive manufactured metal during the 3D printing process.

3D Printing One of the Strongest Stainless Steels

In a breakthrough for industrial manufacturing, scientists reproduced one of the world’s toughest materials using 3D printing.

Four layers of a surface-conducting material (Bi2Te3) between two single layers of a magnetic insulator (MnBi2Te4). This structure creates the conditions to align the manganese spins (red arrows) and support a zero-resistance, spin-polarized current.

Could a Magnetic Sandwich Make Your Electronic Devices Work More Efficiently?

Layers of a surface-conducting material, sandwiched between layers of a magnetic insulator, could lead to more powerful, energy-efficient electronics.

Highly porous MOFs can trap toxic gas molecules and prevent them from entering the atmosphere and can also be used to build sensors. This illustration shows the material’s normal luminescence (left) switched off in the presence of harmful gases (right).

Lying in Wait: MOF Are Traps for Toxic Gases

Researchers used neutrons to study porous metal materials called MOFs that trap toxic gases that are harmful to the environment and human health.

(A) The ultra-intense X-ray beams delivered by the unique superconducting helical undulator. (B) Ultrafast multi-pulse X-ray images. (C) Analysis of a region of interest. (D) A high-resolution velocity map of the near-nozzle spray.

Tiny Cavitation Bubbles Enhance Energy Conversion in Fuel Injectors’ Jets

Ultrafast X-ray imaging created with new technology offers insights into improving the energy efficiency of combustion engines.