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As global temperatures continue to rise, glaciers are melting, and soils with communities of microorganisms are now exposed. Researchers are studying the microorganisms in these soils to determine how they influence carbon flux and climate change.
A multi-institutional team of researchers studied how solar radiation from the sun interacts with individual tar balls. This research, featured on the cover of ACS Publications' Environmental Science & Technology, provides insights into how wildfires influence climate change.
Researchers from the University of Arizona and the Environmental Molecular Sciences Laboratory, a Department of Energy user facility, discovered that that plants can maintain specific microbe partnerships during times of drought, revealing a new level of resilience.
Researchers from the University of Toronto and the Environmental Molecular Sciences Laboratory (EMSL) recently published research demonstrating that pyrite—the most abundant sulfide mineral in the Earth’s crust—is enriched in several trace elements. This is important for understanding past ocean chemistry from analyses of sedimentary pyrite. Knowledge from this research will help scientists use pyrite trace metal concentrations to analyze and quantify early ocean chemistry and, as a result, the ocean’s evolution through time.
A team of scientists led an experimental study to determine the relationships between subpopulations of cells within the biofilm of a model microbe, revealing new insights regarding their potential.
Research highlights the potential significance of ectomycorrhizal fungi diversity in promoting forest ecosystem health and strengthening the symbiotic relationship between mycorrhizae and host plants.
Using a 26-year-old common garden forest, a multi-institutional team of researchers collected fine root samples from four temperate tree species (three deciduous and one coniferous) that varied in their morphology.
A multi-institutional team of researchers developed a protocol to isolate cell types for deep sequencing analysis. They successfully generated the first comprehensive gene expression atlas of the sorghum stem, which revealed cell-type-specific expression patterns, pathways, and underlying regulatory networks.
A multi-institutional team of researchers developed a stand-alone box model to predict aqueous and cloud chemistry of biomass-burning phenols based on laboratory measurements.
A multi-institutional group of scientists identified a particular signature of potassium organic acids that are some of the first of their kind.
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