
Direct Neutrino-Mass Measurement Achieves New, Sub-Electronvolt Sensitivity
An international group of nuclear scientists has restricted the neutrino mass with a new level of sensitivity.
An international group of nuclear scientists has restricted the neutrino mass with a new level of sensitivity.
Precision measurements on the oxygen formation in stellar helium burning use gamma-beams and a Time Projection Chamber.
Adding a little oxygen to particle accelerator structures may make them more efficient and easier to build.
Researchers develop a 2D tomography technique that will enable the search for Mach waves in the smallest droplets of quark-gluon plasma.
The search for “broken symmetry” may offer new insight into nuclear structure.
Scientists studied antimatter in the proton with higher precision than ever before, revealing insights into the particle’s puzzling dynamics.
A recent measurement of the neutron-rich “skin” around lead nuclei reveals new details of neutron behavior and the dynamics of neutron stars
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.