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

Illustration of an eye with the chemical structure for rhodopsin molecules in front of it

Unveiling the Molecular Mechanism of Vision Using Ultrafast X-ray Pulses

How visual rhodopsin responds to light in one of nature’s fastest reactions. 

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.

Graphic showing how a thin film can go through compressive strain on top of a substrate to become superconducting as well as a line graph showing how the most strain induces superconductivity

Unveiling the Link Between High Pressure and Superconductivity

Researchers have learned how to retain superconductivity at ambient pressure in a new class of high temperature superconductors.

(1) Ferroelectrics: polarity switched by electric fields, (b) ferromagnetics: magnetism switched by magnetic fields, (3) ferroelastics: elasticity switched by applied stress, (4) ferrotoroidics (unconfirmed): magnetic domains switched by magnetic fields.

A New Twist in Data Storage? Magnetic Whirlpools in Energy Materials

Mapping a way to ferrotoroidicity: the long-sought fourth ferroic order with magnetic-electric properties that can enable new technologies.

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

A new control technique creates an electron beam with a very dense core. Left: head-on view of the beam. Right: correlation between beam particle position and angle showing nonlinear distortions at the edges. The color scale shows the log of density.

Harnessing Distortions for Denser Particle Beams

The intra-beam repulsion that typically degrades electron beam quality can now be used to improve it

Artist’s impression of how X-rays make it possible to study the distortions of the layers in the microelectronics material. The atoms at the edges of the layers are either squished tighter or pulled apart, creating a bend along the different layers.

Seeing Inside Next-Generation Microelectronics Using X-rays

Scientists found two competing mechanisms that contribute to the deformation of nanosheet materials used in cutting-edge computer components.

An artificial intelligence-driven approach established by advanced characterization (X-ray and thermal imaging) improves printed parts by monitoring 3D printing processes in real time to accurately detect keyhole pores, a typical printing defect.

Detecting 3D-Printing Defects in Real Time

Scientists develop a new approach for detecting defects in metal parts produced by additive manufacturing.

Schematic shows a lithium-air battery cell consisting of a lithium metal anode, air-based cathode, and solid ceramic polymer electrolyte (CPE). Upon discharge and charge, lithium ions (Li+) go from anode to cathode, then back.

Innovative Lithium-Air Battery Design Poised to Increase Energy Storage

A new rechargeable lithium-air battery potentially has four times greater energy density than a traditional lithium-ion battery.

Two synchronized flashes of ultrafast X-rays interact with a molecule. The electrons ionized from the molecule are detected with an energy spectrometer, providing observation of the interaction between the two particles at the attosecond timescale.

Action! Attosecond X-rays Produce Ultrafast Movies

Researchers use an X-ray free-electron laser to film electrons using finely tuned pairs of attosecond flashes.

A warm electrolyte (on the right) generates favorable changes in the photoelectrode surface, resulting in improved reaction efficiency for splitting water into oxygen (O) and hydrogen (H).

More Hydrogen from Hot Water Splitting

A higher electrolyte temperature increases the activity of a thin-film electrode for solar hydrogen generation by 40 percent.