Scientists explore the origin of Aluminum-26 in stars with a nuclear reaction that exploits the fact that neutrons and protons are stunningly similar.
New production methods for cerium-134 advance technologies for imaging human disease and guiding treatment.
A high-speed, high-yield recovery approach for At-211 means improved availability of this cancer-treating isotope.
A new approach for measuring nuclear recoils in superconducting quantum sensors enables the first limits on sterile neutrinos from beryllium-7 decay.
Data from the first observation of a neutron-star collision combined with input from modern nuclear theory narrow the range of neutron star radii.
Experiments reveal the relationship between the density of matter and extreme pressure in stellar objects, putting constraints on models of white dwarf stars
A novel paradigm for pushing energy in a particle accelerator method could dramatically shrink future accelerators.
Scientists find the radioactive nucleus selenium-72 is football-shaped, answering a longstanding question about the nuclear shape of selenium isotopes.
The radii of three proton-rich calcium isotopes are smaller than previously predicted because models didn’t account for two nuclear interactions.
Read more about Why Are These Extremely Light Calcium Isotopes So Small?
Widespread fracturing during lake drainage triggers vertical shafts to form that affect the Greenland Ice Sheet.
The mechanism responsible for creating intense magnetic fields in laser-driven plasmas also helps tear the fields apart.
A non-twisting laser beam moving through magnetized plasma turns into an optical vortex that traps, rotates, and controls microscopic particles, opening new frontiers in imaging.
