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Peering into the Mist: How Water Vapor Changes Metal at the Atomic Level
New insights into molecular-level processes could help prevent corrosion and improve catalytic conversion.
New insights into molecular-level processes could help prevent corrosion and improve catalytic conversion.
Scientists discover key types of microbes that degrade organic matter and release carbon dioxide and methane into the atmosphere.
Researchers can precisely study how different genes affect key properties in a yeast used industrially to produce fuel and chemicals.
Identified genes involved in plant cell wall polysaccharide production and restructuring could aid in engineering bioenergy crops.
How yeast partition carbon into a metabolite may offer insights into boosting production for biofuels.
New model provides more accurate estimates of how fast microbes produce a mercury-based neurotoxin.
Ultrafine aerosol particles produce bigger storm clouds and more precipitation than larger aerosols in pristine conditions.
Scientists explore how drought-tolerant plants communicate to nearby microorganisms, suggesting ways to engineer more resilient bioenergy crops.
Scientists devise new approach that gathers data on the interplay between permafrost, soil, and vegetation.
Distortion of water droplet surface may increase the likelihood of the droplet freezing.
A new modeling framework helps understand the consequences of future sea-ice loss in the Arctic.
Researchers discover how certain bacteria may safeguard plant growth during a drought, making way for strategies to improve crop productivity.
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