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

Left: Superconducting tripole striplines on a substrate inside a high-purity aluminum cylinder. Right: Cross-section showing strip arrangement and electric field behavior in different modes. Each mode is sensitive to different types of energy loss.

Advancing Quantum Technology: Tantalum's Impact on Next Generation Qubits

Enhancing quantum coherence through innovative materials design in superconducting circuits

Representation of the magnitude of the elastic πΣ hadron scattering amplitude showing the double-pole structure that suggests the hadron has a pair of resonances at 1380 megaelectronvolts (MeV) and 1405 MeV, not just one at 1405 MeV.

To Understand a Special Hadron, Researchers Turn to Supercomputers and Quantum Chromodynamics

Scientists Gain new insights into the nature of the puzzling lambda 1405 hyperon resonance and its controversial partner.

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.

Visualization of the evolution of the nuclear size and shape from indium and tin isotopes between the major nuclear shells at N=50 and N=82, where N is the number of neutrons in the nucleus.

Testing the Possible Doubly Magic Nature of Tin-100, Researchers Study the Electromagnetic Properties of Indium Isotopes

Scientists are closing in on a major cornerstone of nuclear physics, Tin-100.

To make element 116, researchers fused isotopes of titanium and plutonium.

New Progress Toward the Discovery of New Elements

Scientists demonstrated a new way to produce the superheavy element livermorium (element 116) with titanium-50.

The dynamics of coupled oscillators, such as those shown here, can be simulated faster with a new quantum algorithm.

Springing Simulations Forward with Quantum Computing

A new quantum algorithm speeds up simulations of coupled oscillators dynamics.

Gravity from mountains on rapidly rotating neutron stars produces ripples in space-time known as gravitational waves. The Laser Interferometer Gravitational Wave Observatory (LIGO) searches for such waves.

Neutron Star Mountains Would Cause Ripples in Space-Time

Extreme stars may have mountains like those on moons in our solar system. If so, they could produce detectable oscillations of space and time.

Ground-based radio telescopes, gravitational wave detectors, and a space-based X-ray telescope (right) all measure neutron stars (top left, shown merging), lending insight into the pairing of different-colored quarks in dense matter (bottom left).

Neutron Star Measurements Place Limits on Color Superconductivity in Dense Quark Matter

Requiring consistency between the physics of neutron stars and quark matter leads to the first astrophysical constraint on this exotic phase of matter.

Artist’s depiction of a proton’s interior. In quantum chromodynamics, the constituent quarks come in three “colors,” along with up and down “flavors.” Also shown are virtual quark-antiquark pairs and the gluons that bind the quarks together.

New Approach Merges Theoretical Fundamentals with Experimental Studies of the Proton’s Structure

A new approach to applying quantum chromodynamics paves the way for a deeper understanding of the strong nuclear interaction.

A neutrino moves through a gas of neutrons and is sensitive to correlations in spin and density in the neutron matter. These correlations determine how much energy transfers from the neutrino to the neutrons.

Improved Spin and Density Correlation Simulations Give Researchers Clearer Insights on Neutron Stars

New lattice simulations compute the spin and density correlations in neutron matter that affect neutrino heating during core-collapse supernovae.

Graphic showing the transverse motion of a quark (green sphere) inside a proton whose spin is aligned to its direction of motion (large yellow arrow).

Calculation Sharpens Imaging of Protons’ Insides

New theory-based approach gives access to quarks’ tiny transverse motion within protons.

Scientists Gain New Insights into How Mass Is Distributed in Hadrons

Nuclear theorists reveal mass distribution within the pion and the proton from first principle numerical calculations.