New material based on common iron ore can help turn intermittent sunlight and water into long-lasting fuel.
Research reveals that giant viruses acquire genes piecemeal from others, with implications for bioenergy production and environmental cleanup.
Researchers find a grass gene affecting how plants manage water and carbon dioxide that could be useful to growing biofuel crops on marginal land.
Teamwork provides insight into complicated cloud processes that are important to potential environmental changes in the Arctic.
A newly discovered metabolic process linking different bacteria in a community could enhance bioenergy production.
These enhanced tools will accelerate gene discovery and characterization, vital for new forms of fuel production.
Aircraft data show that ice particles are smaller and fall faster than models had assumed; correcting this issue in models improves simulation of deep, raining cloud systems.
Data from three Arctic measurement sites show how clouds, temperature, and water vapor impact the Arctic surface energy budget, which could enhance future warming and sea ice melt.
Researchers discover the first CRISPR-Cas9 system in archaea, which may enable new technologies for biological research.
For the first time, scientists analyzed the genetic material of surface microbes that are colonizing the deep subsurface, where they are adapting and thriving.
New model reveals the significant role of microbes in oceanic nutrient and energy.
