New calculations suggest that high energy quarks should scatter wider and faster in hot quark matter than can be accounted for by local interactions.
First measurements of how hypernuclei flow from particle collisions may give insight into the strange matter makeup and properties of neutron stars.
Modern nuclear theory predicts that nucleons appear less “squishy” when probed with neutrinos than was previously inferred from experimental data.
Researchers worked out how to efficiently prepare wave functions for the lithium-6 nuclear ground state and implemented those on quantum hardware.
By reanalyzing the distribution of active protons in nuclei, researchers found a possible solution to a particle physics puzzle involving quarks.
If observed, neutrinoless double-β decay would have changed our view of the Universe.
By reanalyzing the distribution of active protons in nuclei, researchers found a possible solution to a particle physics puzzle involving quarks.
Nuclear physicists find evidence of superradiant states by looking at the alpha decay of excited states in mirror nuclei.
New measurements at RHIC provide evidence for quark ‘deconfinement’ and insight into the unimaginable temperature of the hottest matter on Earth.
Calculations predict the temperature at which bottomonium melts in the hot matter created in heavy ion collisions.
Researchers have resolved a longstanding puzzle in theoretical calculations for heavy ion and electron-ion collision experiments.
Data on protons emitted from wide range of gold-gold collision energies shows absence of a quark-gluon plasma (QGP) at the lowest energy.
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