Making Difficult Quantum Many-Body Calculations Possible
Solving quantum many-body problems with wavefunction matching.
Solving quantum many-body problems with wavefunction matching.
Layers of a surface-conducting material, sandwiched between layers of a magnetic insulator, could lead to more powerful, energy-efficient electronics.
Researchers used neutrons to study porous metal materials called MOFs that trap toxic gases that are harmful to the environment and human health.
Ultrafast X-ray imaging created with new technology offers insights into improving the energy efficiency of combustion engines.
Electron transfer between atomically thin materials triggers the ultrafast release of heat.
Scientists chart a path to sub-femtosecond hard X-ray Free-Electron-Laser pulses powered by compact plasma-based accelerators.
Recent advances enable simulations near a possible critical endpoint of the transition between the quark gluon plasma and a hadron liquid.
New nuclear physics measurements shed light on the synthesis of heavy elements in stars.
The Facility for Rare Isotope Beams opens a new research avenue and observes three new rare isotopes.
Nuclear physicists shatter a nearly 30-year-old record for the measurement of parallel spin within an electron beam.
Scientists have detected nuclear decay by observing the recoil of a dust-sized particle when a single nucleus within it decays.
High-surface area silicon improves light-driven reactions of carbon dioxide.