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

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.

Artist’s representation of camelina seeds with contrasting seed coat colors and oil amounts. Disruption of the TT8 gene in camelina changed the regular brown seed color to light yellow and enhanced oil accumulation.

Engineered Yellow-Seeded Camelina Packs More Oil

Scientists use gene editing to create a yellow-seeded camelina that may boost oil yield.

Visualization of Bragg diffraction peaks in an undeformed bi-crystal gold sample. The height denotes photon counts. This data was produced at the Advanced Photon Source and processed at the ThetaGPU supercomputer using AI models.

Bringing FAIR Principles to AI Models

Researchers extend findable, accessible, interoperable, and reusable principles for datasets to scientific datasets and software.

Researchers have long thought pure niobium superconducting radiofrequency cavities were best for particle accelerators. Researchers are now using a toolkit to learn how to add impurities to the cavities to make them smoother—and more efficient.

Smoother Surfaces Make for Better Particle Accelerators

An enhanced topographic analysis toolkit for forecasting and improving particle accelerator performance is helping scientists build better accelerators.

Smoother Surfaces Make for Better Particle Accelerators

An enhanced topographic analysis toolkit for forecasting and improving particle accelerator performance is helping scientists build better accelerators.

Wavefunction matching replaces the short distance part of the two-body wavefunction for a realistic interaction with that of a simple easily computable interaction. The result is a new interaction that can be handled in quantum many-body calculations.

Making Difficult Quantum Many-Body Calculations Possible

Solving quantum many-body problems with wavefunction matching.

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.