For the First Time, Scientists Rigorously Calculate Three-Particle Scattering from Theory
Nuclear theorists demonstrate a new method for computing the strengths of subatomic interactions that include up to three particles.
Nuclear theorists demonstrate a new method for computing the strengths of subatomic interactions that include up to three particles.
If physicists can find it, color transparency in protons could offer new insight into the particles that build our universe.
A new machine learning system diagnoses particle accelerator component issues in real-time.
A result 20 years in the making: Most precise measurement yet of the lifetime of the charge-neutral pion that keeps protons and neutrons together.
Nuclear theorists put pen to paper and code to computer to detail this subatomic particle’s inner structure.
Scientists conduct the first direct probes of the interactions between protons and neutrons inside nuclei.
Physicists get closer to solving the proton radius puzzle with unique new measurement of the charge radius of the proton.
Built with detector technologies used in nuclear physics experiments, the system monitors radiation treatments in hard-to-reach areas.
A precision measurement of the proton’s weak charge narrows the search for new physics.
Physicists develop a universal mathematical description that suggests that proton-neutron pairs in a nucleus may explain why their associated quarks have lower average momenta than predicted.
Pressure in the middle of a proton is about 10 times higher than in a neutron star.
The newly upgraded CEBAF Accelerator opens door to strong force studies.