Scientists find that water-related energy consumption is increasing across the globe, with pronounced differences across regions and sectors.
Data derived from these instruments will support climate model simulations of cloud processes.
Understanding differences in modeling soil water will help scientists simulate how this moisture affects the climate.
Mass spectrometry and high-performance computing combined, allowing scientists to study proteins that link internal processes to community attributes.
Natural carbon dioxide production from deep subsurface soils contributes significantly to emissions, even in a semiarid floodplain.
New analysis uses detection and attribution methods to establish multiyear trends of vegetation growth in northern-extratropical latitudes.
Community composition is vital to managing native grasslands amid climate and precipitation variations.
Genetic approaches will aid development of higher biomass-yielding, sustainable trees for bioenergy feedstocks.
“Master regulator” gene will facilitate management and breeding of trees better adapted to changing environments.
Better understanding could lead to more cost-effective production of cellulosic biofuels.
Recycling waste from biofuel production could lower cost for future biorefineries.
A novel E. coli fatty acid biosynthesis system could more efficiently convert biomass to desired products.
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