Scientists use engineered gene circuits in plants to control gene expression and root architecture.
Microbes in Arctic soils are equipped to respond rapidly to the diverse effects of ongoing permafrost thaw.
Theoretical study exploits precision of new heavy ion collision data to predict how gluons are distributed inside protons and neutrons
High-energy proton experiments optimize production of medical imaging isotopes while providing insight into how to protect astronauts from space radiation.
A weak proton emission following beta decay constrains the formation of elements in stellar nova explosions and determines their peak temperature.
Long predicted by theory with support from supercomputers, this combination of neutrons advances nuclear physics
Quantum technique accelerates identification of entangled materials.
Cloud microphysics affect precipitation extremes on multiple time scales in climate models.
A new UV-visible protein allows researchers to see gene expression in plants without special equipment.
Researchers used deep learning methods to estimate the subsurface permeability of a watershed from readily available stream discharge measurements.
The Facility for Rare Isotope Beams has demonstrated an innovative liquid-lithium charge stripper to accelerate unprecedentedly high-power heavy-ion beams.
Research finds that the effects of drought and wildfire on soil bacterial communities fade in deeper soils.
