Nuclear theorists demonstrate a new method for computing the strengths of subatomic interactions that include up to three particles.
Scientists find strong evidence for the long-predicted Breit-Wheeler effect—generating matter and antimatter from collisions of real photons.
The new “rodeo algorithm” approach for preparing energy states of complex systems on a quantum computer is exponentially faster than other algorithms.
Nuclear scientists devise an indirect method of measuring the speed of sound in matter created in heavy-ion collisions.
The energy of a key resonance in sodium destruction is found, affecting our understanding of globular cluster evolution.
Scientists measure radioactive molecules at the extremes of physics.
Measurements of particle “flow” and hot matter created in low-energy collisions provide key data in understanding nuclear phase transition.
Measurements of nuclear charge radii and state-of-the-art nuclear models challenge the magic of neutron number 32 in potassium isotopes.
If physicists can find it, color transparency in protons could offer new insight into the particles that build our universe.
Research on techniques for studying the chemical properties of superheavy elements might also help recover a strategically important metal.
A key reaction in the slow neutron-capture process that forms elements occurs less frequently than previously thought.
Scientists explore the origin of Aluminum-26 in stars with a nuclear reaction that exploits the fact that neutrons and protons are stunningly similar.
