Science Highlights

Exploring the gluon saturation in a large nucleus is one of the goals of the future Electron-Ion Collider. Researchers proposed a nucleon energy-energy correlation approach that provides a unique probe of the onset of gluon saturation.

New Method Could Explore Gluon Saturation at the Future Electron-Ion Collider

Theorists propose nucleon energy-energy correlator as a probe to the gluon saturation phenomena at the future electron-ion collider.

Left: partitions where the set of blue points occupy one region and the set of black points another region, similar to how many systems work. Right: the partitions that occur in nuclei, where the partitions of blue and black points occupy the same regions.

Entanglement Entropies of Nuclear Systems Grow as the Volume of those Systems

Quantum entanglement changes in atomic nuclei in ways that differ from other systems.

Left: “Mirror” nuclei lithium-8 and boron-8 undergo beta decay, then split into two alpha particles. Right: Radioactive ions from the ATLAS accelerator at Argonne National Laboratory are suspended in vacuum using an ion trap device.

New Beta-Decay Measurements in Mirror Nuclei Pin Down the Weak Nuclear Force

Scientists develop a new method to characterize the properties of one of the four fundamental forces of nature.

A scanning electron microscope image of the superconducting nanowire switch. Large electric output currents in the green channel can be switched on and off by small input currents in the red gate terminal. Blue is the superconducting ground plane.

Superconducting Electronics Show Promise for Future Collider Experiments

Scientists test a novel design for superconducting switches in magnetic fields.

The types of information in the NUBASE Nuclear Data library and the library’s other applications.

Database Supplies Recommended Key Properties for All Known Nuclei

Scientists in nuclear physics, astrophysics, energy, national security, and medicine use a source of recommended nuclear data to advance their research.

Theoretical calculations predict a complex excited state (0+) for helium-4 (4He) at the 20.21 MeV energy level. This state involves a coupling of three cluster configurations: helium-3 and a proton, helium-3 and a neutron, and two helium-2 nuclei.

New Calculations Solve an Alpha Particle Physics Puzzle

A new experimental measure of Helium-4’s transition from its ground energy state to an excited state closes an apparent gap with theoretical predictions.