Physicist David Newman’s work in magnetic confined fusion is on a problem that develops as plasma heats up, called turbulence and turbulent transport.
Researchers demonstrated a new type of optical nanoscopy that can measure electron dynamics in semiconductors, with high resolution.
New analysis of black hole collisions shows more details and reveals "nonlinear" effects contained in gravitational waves.
According to a new study, nuclear physicists have found a way to peer inside the deepest recesses of atomic nuclei.
A new partnership received funding to advance understanding of environmental conditions at the neighborhood level & prioritize environmental justice.
A Boston College-led team has developed a new technique to image and understand the origin of photocurrent flow in Weyl semimetals.
Justin Kennemur is leading the synthesis efforts aimed at creating novel materials that can replace today’s fluorine-based polymer membranes.
A team experimentally observed silicon-rich crystal formation in iron-hydrogen alloy liquid at conditions expected for the Earth’s outer core.
The research studies and manipulates fractionally charged anyons in fractional quantum Hall regime, a testbed for exploring the impact of topology.
An ISU professor will transition their simulations of atomic nuclei from high-performance, classical computers to next-generation quantum computers.