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

The diagram shows the evolution of a copper surface from metal through OH adsorption to Cu2O and Cu(OH). Modulating the voltage enables the X-ray to reveal the surface chemistry as the reaction occurs.

Accessing Dynamic Electrochemical Interfaces

A new technique reveals ultrafast processes in electrode-electrolyte interfaces under operating conditions.

KATRIN scientists test the system of magnets that control the fields inside the spectrometer.

KATRIN Narrows Down the Range of Neutrinos’ Mass

A direct search shows that neutrinos are at least a million times lighter than electrons.

Two nitric oxide molecules are irradiated with an attosecond X-ray pulse and release an electron. This is an example of the photoelectric effect.

Interactions Between X-Rays and Matter Provide Insights into How Electrons Behave in Molecules

By measuring the delay between when a molecule absorbs a photon from an X-ray and emits an electron, scientists gained insight into how electrons interact.

Germanium semiconductor (grey) with dilute silicon (Si) and tin (Sn) atoms (red and blue). Si and Sn do not spread out randomly. They often group together in Si-Ge-Sn sets, showing a short-range order that was previously predicted but not confirmed.

Uncovering Hidden Atomic Patterns in Semiconductors

Advanced microscopy reveals motifs of trace atoms in semiconductors, paving the way for new microelectronics designed atom by atom.

(Left) Projections of the reconstructed 6D beam distributions. The maps denote beam density in 15 position-momentum combinations and curves in 6 positions (x, y, z) or momenta (px, py, pz). (Right) 3D density map of beam particles in z−y−py space.

Combining Physics and Machine Learning to Analyze Particle Beams in Accelerators

A new technique combining physics and machine learning enables scientists to quickly reconstruct details of particle beams without the need for large datasets.

Pyrocumulonimbus clouds are intense, fire-induced thunderstorms that inject significant amounts of aerosols and gases into the atmosphere.

Modeling Storm Clouds Caused by Extreme Wildfires

A new study integrates fire processes into an Earth system model to help scientists simulate and better understand the impacts of pyrocumulonimbus clouds.

This is a representation of the spin-wave current detected by X-rays. A temperature gradient (blue and red) generates a spin wave current (orange arrows and wave traces) in the yttrium iron garnet sample. X-ray beams hit the sample and scatter back.

Tracing Invisible Spin Currents

Scientists directly observed spin wave currents using advanced Resonant X-ray Scattering.

The QUANT-NET research team has designed a two-level control framework for quantum networks. This two-level control framework and scheduler are being deployed and evaluated in the QUANT-NET testbed.

Building a Flexible Control Framework for Quantum Networks

A new control framework enables automated, reliable control of quantum networks, paving the way for practical deployment.

This image shows changes in pressure at the plasma’s outer midplane. It shows how increasing density changes plasma behavior from large potentially damaging instabilities at low density to low-level constant turbulence without bursts at high density.

Protecting Against Large Damaging Energy Bursts in Fusion Energy Devices

Scientists found a potential way to suppress large damaging edge-localized modes, providing an approach to protect future devices.

Researchers tested multiple distillable amine-based solvents to see how they performed in pretreatment processes for biomass. They found butylamine was a superior solvent.

A Standout Solvent for Today’s Biorefineries

Researchers identify butylamine as a promising solution to many challenges at biorefineries.

Researchers engineered E. coli to use formate as a feedstock to achieve fast growth. This could allow manufacturers to use it to produce precursors for biofuels and bioplastics.

Exploring the Potential of a Formate-Based Bioeconomy

Researchers demonstrated an efficient strain of bacteria for bioproduction that grows on the promising feedstock formate.

Illustration of an undulator’s magnetic field being manipulated to generate ultrafast X-ray pulses. The illustration compares the process to music: Instead of individual notes, researchers played a full melody.

Demonstrating Unprecedented Control of X-ray Pulses

Researchers have used an undulator’s magnetic field to generate and control ultrafast X-ray pulses.