Nuclear theorists demonstrate a new method for computing the strengths of subatomic interactions that include up to three particles.
A few common bacteria use most of the carbon in soil
Bacteria collection opens new directions for research on cottonwoods, poplars, and other trees useful for biofuel and other applications.
Scientists find strong evidence for the long-predicted Breit-Wheeler effect—generating matter and antimatter from collisions of real photons.
First observation of embedded magnetic islands paves way for improved fusion reactor designs.
Chromium defects in silicon carbide may provide a new platform for quantum information
Researchers improve their scientific understanding of heterogeneous catalysis by imaging the gas just above the surface of the catalyst.
Ecological assembly and source tracking models characterize the initial assembly of the poplar microbiome across plant-associated habitats.
Identification of an enzyme that microbes deploy in the presence of plants leads to discovery of candidate genes involved in root colonization.
The new “rodeo algorithm” approach for preparing energy states of complex systems on a quantum computer is exponentially faster than other algorithms.
A novel mathematical formulation accurately solves water flow in geometrically complicated soil structures, including overturned soil layers and other disturbances.
Nuclear scientists devise an indirect method of measuring the speed of sound in matter created in heavy-ion collisions.
