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

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.

Researchers study neutron star crusts by simulating neutron matter then adding “hidden” neutrons to mediate interactions between “real” neutrons. Next, neural networks construct a quantum wave function of neutron matter’s normal and superfluid phases.

Probing Neutron Star Crusts with Artificial Neural Networks

Scientists find evidence of superfluidity in low-density neutron matter by using highly flexible neural-network representations of quantum wave functions.

Artist’s depiction of the aluminum-22 nucleus if it exists in a halo state. This nucleus contains 13 protons (red) and 8 neutrons (blue). Halo nuclei are characterized by having one or more nucleons existing at an extended distance from a compact core.

Researchers Obtain the First High-Precision Mass Measurement of Aluminum-22

The Facility for Rare Isotope Beams enables a high-precision mass measurement at the edge of the nuclear chart.

Researchers have long thought pure niobium superconducting radiofrequency cavities were best for particle accelerators. Researchers are now using a toolkit to learn how to add impurities to the cavities to make them smoother—and more efficient.

Smoother Surfaces Make for Better Particle Accelerators

An enhanced topographic analysis toolkit for forecasting and improving particle accelerator performance is helping scientists build better accelerators.

Wavefunction matching replaces the short distance part of the two-body wavefunction for a realistic interaction with that of a simple easily computable interaction. The result is a new interaction that can be handled in quantum many-body calculations.

Making Difficult Quantum Many-Body Calculations Possible

Solving quantum many-body problems with wavefunction matching.

This image shows a snapshot of the order parameter in a fluctuating quark gluon liquid. Green regions are in the quark gluon phase, blue regions in the hadron phase.

Simulating a Critical Point in Quark Gluon Fluid

Recent advances enable simulations near a possible critical endpoint of the transition between the quark gluon plasma and a hadron liquid.

A simulation of a rapidly accreting white dwarf showing a proposed site for the intermediate (i) process and the Summing NaI (SuN) detector. The research studied the 139Ba+n reaction, constrained by the beta decay of 140Cs into 140Ba.

Nuclear Physics Experiment Helps Identify Conditions for a New Astrophysical Process

New nuclear physics measurements shed light on the synthesis of heavy elements in stars.

Team members pose in the clean room (left). Thermal image of the 10.4 kW uranium-238 beam on the target (top right). Three never-before-seen isotopes, shown to the right of the red line on the particle identification plot (bottom right).

Scientists Accelerate Uranium Beam with Record Power

The Facility for Rare Isotope Beams opens a new research avenue and observes three new rare isotopes.

The Compton polarimeter’s laser system, used to measure electrons’ parallel spin, is aligned during the Calcium Radius Experiment in Hall A of the Continuous Electron Beam Accelerator Facility at the Thomas Jefferson National Accelerator Facility.

Laser-Sharp Look at Spinning Electrons Sets the Stage for New Physics Discoveries

Nuclear physicists shatter a nearly 30-year-old record for the measurement of parallel spin within an electron beam.

Science Highlights