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.
A new quantum algorithm speeds up simulations of coupled oscillators dynamics.
Experiments show that applied voltage can dramatically alter the magnetic properties of quantum materials.
Researchers combine solar energy, electrochemistry, and thermal catalysis to remove the need for fossil fuel-driven chemical conversions.
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.
Theorists propose a new approach to electroluminescent cooling that works like inverted solar photovoltaic cells.
Ultrafast electron diffraction imaging reveals atomic rearrangements long suspected to be crucial in the photochemistry of bromoform.
Quantum ghost imaging of live plants at light levels lower than starlight gives new perspectives on plant processes.
A new approach to applying quantum chromodynamics paves the way for a deeper understanding of the strong nuclear interaction.
Integrating machine learning with real-time adaptive control produces high-performance plasmas without edge instabilities, a key for future fusion reactors.