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

Artistic conception of a fast-moving lead nucleus colliding with fixed target neon-20 gas.

Bowling Near the Speed of Light

Collisions of lead with smaller nuclei allow taking images of the fluctuating nuclear shape

(a-d) Atomic force microscopy (AFM) images of niobium (Nb) based superconducting qubits at (a,c) room temperature and (b,d) cryogenic temperatures. At low temperatures, the “hills” represent the formation of niobium hydrides.

Spotting a New Culprit in the Hunt for Quantum Noise

Microscopes, x-rays, and spectroscopy tools join forces to identify defects that interfere with delicate superconducting qubit properties.

Neon-20 nuclei have an elongated shape like a bowling-pin. Collisions of these nuclei create signals in how particles flow that clarify the role of nuclear geometry.

Using Nuclear Shapes to Study How Particles Flow in Collisions Between Light Ions

Collisions of oxygen and neon nuclei show how nuclear shapes can influence collective particle flow in small systems.

High-speed X-ray radiography of thin plate laser welding and derived scaling laws demarking process windows for welds with and without humping.

X-rays Reveal Why High-Speed Welding Goes Wrong

Scientists used powerful X-rays and computer models to uncover what causes surface defects in laser welds—and how to stop them.

This illustration shows multilayer Laue lenses within the microscope focusing incoming X-rays on the microelectronics sample. It reveals the sample’s internal, nanoscale structure.

One Day's Work in an Hour: A Versatile, Fast-scanning, X-ray Microscope

Innovative, high-resolution X-ray microscopy system generates 3D images 20 times faster than the previous system.

Artist impression of a trapped radioactive vapor decaying into a coherently-beamed stream of neutrinos (symbolized by v).

Physicists Propose a New Kind of Laser That Would Fire Neutrinos

A potential tool could use Bose Einstein condensates to produce intense beams of neutrinos.

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.

A 3D view of the energy densities of electron neutrinos, electron anti-neutrinos, heavy-lepton neutrinos and heavy-lepton anti-neutrinos about five milliseconds after neutron stars collide.

When Neutron Stars Collide, Neutrinos Change Flavors

Scientists have developed a simulation of the merger of two neutron stars that includes the oscillation of different neutrino flavors into one another.

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.