Oxygen Tweaking May Be the Key to Optimizing Particle Accelerators
Modeling the diffusion of oxygen into accelerator cavities allows scientists to tailor their properties.
Modeling the diffusion of oxygen into accelerator cavities allows scientists to tailor their properties.
Scientists are closing in on a major cornerstone of nuclear physics, Tin-100.
Scientists demonstrated a new way to produce the superheavy element livermorium (element 116) with titanium-50.
Extreme stars may have mountains like those on moons in our solar system. If so, they could produce detectable oscillations of space and time.
Requiring consistency between the physics of neutron stars and quark matter leads to the first astrophysical constraint on this exotic phase of matter.
A new approach to applying quantum chromodynamics paves the way for a deeper understanding of the strong nuclear interaction.
New lattice simulations compute the spin and density correlations in neutron matter that affect neutrino heating during core-collapse supernovae.
New theory-based approach gives access to quarks’ tiny transverse motion within protons.
Nuclear theorists reveal mass distribution within the pion and the proton from first principle numerical calculations.
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.
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