
Creating and Studying Radioactive Molecules Advances Nuclear Structure and Fundamental Symmetry Studies
Scientists measure radioactive molecules at the extremes of physics.
Scientists measure radioactive molecules at the extremes of physics.
Actinide tetrafluorides exhibit significant variations in their electronic structures despite having nearly identical crystal structures.
Interactions of quantum “quasiparticles” demonstrate unusual fluid flow.
New measurements show that fast flows in a tokamak plasma help remove and prevent impurities.
New concept would deliver continuous electricity while reducing cost and risk.
Microscopic features of neptunium dioxide control how contaminants dissolve in underground disposal of spent nuclear fuel.
Measurements and modeling demonstrate that perturbations to the magnetic field in a tokamak fusion plasma can suppress high-energy runaway electrons.
Measurements of particle “flow” and hot matter created in low-energy collisions provide key data in understanding nuclear phase transition.
New research indicates reversing the conventional shape of plasmas could help with fusion reactor operation.
Promising study details how radioactive agents could be sent directly to cancer cells.
A team studied some of the smallest particles in the Universe on the nation’s fastest computer, Summit at Oak Ridge National Laboratory.
Scientists engineer materials’ electrical and optical properties with plasmon engineering