Discovery of Low-lying Isomeric States in Cesium-136 Has Applications in Particle Astrophysics
Measurements of the nuclear structure of cesium-136 open a new channel for measurements of astrophysical neutrinos and searches for dark matter.
Measurements of the nuclear structure of cesium-136 open a new channel for measurements of astrophysical neutrinos and searches for dark matter.
Machine learning and artificial intelligence accelerate nanomaterials investigations.
A new microscopy technique measures atomic-level distortions, twist angles, and interlayer spacing in graphene.
Department of Energy user facility helps probe questions from changes in the structure of nuclei to nuclear reactions that shape the Universe.
A new system for detecting photons in laser-powered quantum computers brings these systems closer to reality.
Researchers examine the structure of the low-energy nuclear states of carbon-12 using nuclear lattice effective field theory.
Simulations of binary neutron star mergers suggest that future detectors will distinguish between different models of hot nuclear matter.
This new Laue lens system received a 2022 Microscopy Today Innovation Award.
Laser-based additive manufacturing produces high-entropy alloys that are stronger and less likely to fracture.
Computation and simulations show that different types of collisions compete to determine the way energy is transferred between particles and plasma waves.
Novel techniques allow the first direct observation of a predicted effect that results in the suppression of gluon radiation emitted by a heavy quark.
New tools borrowed from quantum computing will improve the detection of X-rays and gamma-rays.