Illuminating Magnetic Turbulence in Fusion Plasmas
Electromagnetic waves are used to internally identify turbulent magnetic fluctuations in 100-million-degree fusion plasmas.
Electromagnetic waves are used to internally identify turbulent magnetic fluctuations in 100-million-degree fusion plasmas.
State-of-the-art X-ray techniques found hidden damage in neutron irradiated silicon carbide, a possible structural material for future fusion reactors.
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.
Measurements and modeling demonstrate that perturbations to the magnetic field in a tokamak fusion plasma can suppress high-energy runaway electrons.
New research indicates reversing the conventional shape of plasmas could help with fusion reactor operation.
Research on techniques for studying the chemical properties of superheavy elements might also help recover a strategically important metal.
DIII-D researchers create barriers to separate core heat from the cooler edge of a tokamak
New simulations show diamond shells can cool plasmas more efficiently and prevent runaway electrons
Extreme-scale turbulence simulation and AI discover a formula to predict the crucial exhaust heat-load width in future tokamak fusion reactors.
Researchers use a supercomputer to understand the mysterious “isotope effect” for better fusion reactors.
Researchers address the challenge of integrating the hot core and the cooler edge of a fusion plasma.