The study linked CO2 production to the seasonal uptake of water by tree roots and the surrounding microbial communities many meters below the surface.
The interdisciplinary study found that carbon dioxide levels stimulated soil respiration twice as much under low as under high nitrogen supply.
Microbial electrosynthesis, in which incoming electrons are fed to an engineered microbe, would convert carbon dioxide into non-carbon molecules.
Using a material known as magic-angle twisted bilayer graphene, the team explored how interacting electrons give rise to surprising phases of matter.
System uses machine learning to analyze boundaries between crystal grains, allowing for selection of desired properties in a new metal.
A quantum effect in topological semimetals demonstrated by MIT researchers could allow for the utilization of an untapped energy source.
The discovery is a key development for efforts to weave technological capabilities into clothing and accessories.
The CQNET/FQNET collaboration presents results on state-of-the art quantum teleportation fidelity.
The team found that microorganisms use iron as a food source, thereby releasing the bound organic carbon into the water in the soil.
Princeton researchers set out to map with ultrafast laser spectroscopy the progress of a photoinduced electron transfer reaction.