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

Illustration showing a crystal structure, with balls connected by lines and a blue ball increasing in size moving above the structure

Thin Materials and Fat Electrons: A Recipe for New Quantum Phenomena

The 2D material cerium silicon iodide contains the same heavy electrons responsible for heavy fermion physics, something so far seen only in 3D materials.

The lattice arrangement in a magnetic iron-germanium metal frustrates the movement of electrons (blue and silver spheres). This gives rise to collective behavior such as charge density waves, which form at low temperatures in this material.

Uncovering and Controlling Electron Charge Waves in Quantum Materials

An unexpected electron behavior called charge density waves in an iron-germanium metal material presents a new paradigm in emergent quantum phenomena.

Drawing illustrates in 2-D how electrical conductivity (red) tends to form in the direction of greater mechanical strain (yellow arrows). This property could enable controlling a material’s thermoelectric capabilities via chemical or mechanical methods.

Hot on the Trail of a Thermoelectric Material with High-Conductivity but Slow Thermal Transfer

A “neutron camera” device reveals how a thermoelectric material maintains an overall crystalline structure despite local dynamic disorder

This sample of niobium has been treated in a process that is typical for preparing particle accelerator components. Tests have revealed how adding oxygen to such components makes them more efficient.

Oxygen Tweaking May Be the Key to Optimizing Particle Accelerators

Modeling the diffusion of oxygen into accelerator cavities allows scientists to tailor their properties.

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.

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.

Left: Nickel ions in Ni2Mo3O8 (spheres inside center of polygons) form a honeycomb lattice of tetrahedral (green) and octahedral (blue) polygons. Right: Excitations of the magnetism from the tetrahedral polygons form a neutron scattering pattern (orange).

What If a Nonmagnetic Material Could Be Magnetic?

Electric fields in a crystal of Ni2Mo3O8 create spin excitons and elusive magnetic order.

Depiction of the newly discovered magnetic order of nickel spins (arrows) in nickel monosilicide as revealed by neutron diffraction (background) for the two sites of nickel (spheres).

A Surprising Discovery: Magnetism in a Common Material for Microelectronics

For the first time, researchers discovered magnetic order at high temperature in a metal widely used by the electronics industry.

3D-Printed Alloys Offer Improved Strength and Ductility

Laser-based additive manufacturing produces high-entropy alloys that are stronger and less likely to fracture.

Researchers Use a Novel Approach to Design a COVID-19 Antiviral Drug

Solving atomic structure and binding for improved antiviral drugs.

Plastic Deformation Engineering Dramatically Enhances Quantum Phenomena

Scientists use a common engineering approach to enhance the superconductivity and induce ferroelectricity in the quantum material strontium titanate.

Halide Perovskite Material Exhibits Liquid-Like Atomic Vibrations

Experiments examine atomic disorder and dynamics that could explain beneficial optical properties.