Probing Neutron Star Crusts with Artificial Neural Networks
Scientists find evidence of superfluidity in low-density neutron matter by using highly flexible neural-network representations of quantum wave functions.
Scientists find evidence of superfluidity in low-density neutron matter by using highly flexible neural-network representations of quantum wave functions.
The Facility for Rare Isotope Beams enables a high-precision mass measurement at the edge of the nuclear chart.
An enhanced topographic analysis toolkit for forecasting and improving particle accelerator performance is helping scientists build better accelerators.
Solving quantum many-body problems with wavefunction matching.
Recent advances enable simulations near a possible critical endpoint of the transition between the quark gluon plasma and a hadron liquid.
New nuclear physics measurements shed light on the synthesis of heavy elements in stars.
The Facility for Rare Isotope Beams opens a new research avenue and observes three new rare isotopes.
Nuclear physicists shatter a nearly 30-year-old record for the measurement of parallel spin within an electron beam.
Scientists have detected nuclear decay by observing the recoil of a dust-sized particle when a single nucleus within it decays.
A new calculation helps scientists understand how matter formed out of the hot, dense soup of subatomic particles created by the Big Bang.
Charge radii measurements of silicon isotopes test nuclear theories and guide descriptions of nuclear matter.
Researchers find that the quantum flavor and momentum states of the neutrinos in a supernova are strongly entangled through frequent interactions.