Science Highlights

Image of the emission of 4 neutrons (blue spheres) from the exotic nucleus oxygen-28, which consists of 8 protons (red spheres) and 20 neutrons.

Not-Quite “Magic” Oxygen-28 Observed for the First Time

An almost-bound isotope of oxygen undergoes four-neutron decay that challenges theory.

The modified Majorana module in the assembly glovebox with germanium detector crystals and tantalum samples installed.

Searching for the Decay of Nature’s Rarest Isotope: Tantalum-180m

The first results from the MAJORANA experiment dramatically improve current limits on this rare isotope’s decay.

Nitrogen-9 decays by first emitting one proton, generating carbon-8, then two protons, generating beryllium-6, and finally two more protons, with the resulting residue of a stable alpha particle.

The “Nested Doll” Nucleus Nitrogen-9 Stretches the Definition of a Nucleus to the Limit

Nitrogen-9 has only two neutrons to its seven protons and decays to an alpha particle by emitting five of its protons in stages.

Schematic illustration of the density of the Dirichlet distribution for true model mixing.

Statisticians and Physicists Team Up to Bring a Machine Learning Approach to Mining of Nuclear Data

Bayesian statistical methods help improve the predictability of complex computational models in experimentally unknown research.

A proton’s valence quarks (blue, red, and green), quark-antiquark pairs, and gluons (springs). Scalar gluon activity (pink) extends beyond the electric charge radius (orange) that surrounds the gluonic energy core (yellow).

Scientists Locate the Missing Mass Inside the Proton

Nuclear physicists have found the location of matter inside the proton that comes from the strong force - a fundamental force that holds protons together.

Measuring the Thickness of the Neutron Skin with Ultra-Relativistic Heavy Ion Collisions

Researchers determined the neutron skin of lead-208 from experimental data collected in lead-lead collisions at the CERN Large Hadron Collider.

Electrons emitted in radioactive beta decay in a magnetic field create radio waves or microwaves, which are then picked up by antennas to learn about the decay process and the particles they produce.

Physicists Remotely Sense Radioactive Decay to Probe Fundamental Forces and Particles

The Project 8 and He6-CRES collaborations use a new technique to set an upper limit on neutrino mass and prepare to test the nature of the weak force.

A representation of the machine learning approach used to classify sulfur-38 nuclei (38S) from all other nuclei created in a complex nuclear reaction (left) and the resulting ability to gain knowledge of the unique sulfur-38 quantum “fingerprint” (right).

Machine Learning Techniques Enhance the Discovery of Excited Nuclear Levels in Sulfur-38

Forefront nuclear physics capabilities and machine-learning data analyses combine to generate new information on quantum energy levels in sulfur-38.

A cartoon of free-streaming hadrons emerging from quark-gluon plasma.

How Do Quark-Gluon-Plasma Fireballs Explode into Hadrons?

Scientists translate predictions of hydrodynamics into experimentally observable particle patterns.

A pictorial rendition of the proton-proton fusion chain in the Sun. The fusion of a proton with beryllium-7 produces a boron-8 nucleus that later decays emitting neutrinos that can be detected on Earth.

Novel Theory-Based Evaluation Gives a Clearer Picture of Fusion in the Sun

Theoretical calculations and experimental data combine to reduce uncertainty in a key reaction rate in modelling high-energy solar neutrinos.

Revealed: Quantum Entanglement among Quarks

Quantum simulations reveal the presence of entanglement among the quarks produced in high energy collisions.

Unlocking the Secrets of the Universe through Neutrinoless Double Beta Decay

Scientists investigate neutrinoless double beta decay through neutrino mass and the nuclear structure of germanium-76.

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