NP Highlights

The sigma forms in pion collisions. The graph shows pion-pion scattering as a function of energy. The function is fitted to computer-generated data (black points), with the sigma’s mass and decay rate (gray circle) shown where the function is infinite.

April 11, 2025

A Subatomic Challenge Resolved: Supercomputer Calculations Produce the First Accurate Theoretical View of the Sigma Meson

Nuclear physicists extract the sigma meson with unprecedented accuracy

Drawing of real charged particle tracks from a collision of two uranium nuclei, shown exaggerated in size and flattened by the effects of traveling close to the speed of light, over a sketch of the STAR detector at the Relativistic Heavy Ion Collider.

April 7, 2025

Imaging Nuclear Shapes by Smashing Them to Smithereens

Scientists use high-energy heavy ion collisions in a new way to reveal subtleties of nuclear structure with implications for many areas of physics.

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

April 4, 2025

New Progress Toward the Discovery of New Elements

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

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.

April 1, 2025

Oxygen Tweaking May Be the Key to Optimizing Particle Accelerators

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

In nuclear beta decay an up quark ‘u’ in a proton converts into an up down quark ‘d,’ turning the proton into a neutron and emitting a positron and a neutrino. This work affects interpretation of beta decay measurements across the chart of nuclides.

March 26, 2025

New Precise Calculation of Nuclear Beta Decays Paves the Way to Uncover Physics Beyond the Standard Model

Theorists identify new effects needed to compute the nuclear beta decay rate with a precision of a few parts in ten thousand.

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.

March 19, 2025

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.

An artist’s impression of a quantum electrodynamics simulation using 100 qubits of an IBM quantum computer. The spheres and lines denote the qubits and connectivity of the IBM quantum processor; gold spheres denote the qubits used in the simulation.

March 14, 2025

Nuclear Physicists Create Scalable Quantum Circuits to Simulate Fundamental Physics

Researchers developed and executed algorithms for preparing the quantum vacuum and hadrons on more than 100 qubits of IBM quantum computers.

An artist’s impression of an analog quantum computer in which atoms are manipulated by lasers to simulate quantum many-body systems.

March 10, 2025

Scientists Take an Important Step toward Mitigating Errors in Analog Quantum Simulations of Many-Body Problems

A new framework for quantifying uncertainties increases the predictive power of analog quantum simulations.

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).

January 13, 2025

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.

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.

January 6, 2025

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.

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