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Decomposition of urban atmospheric carbon in Sonoran Desert soils
Authors:Jason P. Kaye  Sara E. Eckert  Daniel A. Gonzales  Jonathan O. Allen  Sharon J. Hall  Ryan A. Sponseller  Nancy B. Grimm
Affiliation:1.Department of Crop and Soil Sciences,The Pennsylvania State University,University Park,USA;2.Department of Chemical Engineering,Arizona State University,Tempe,USA;3.Department of Civil & Environmental Engineering,Arizona State University,Tempe,USA;4.Allen Analytics LLC,Tucson,USA;5.School of Life Sciences,Arizona State University,Tempe,USA;6.Department of Forest Ecology and Management,Swedish University of Agricultural Sciences,Ume? SE-901 83,Sweden
Abstract:Urban atmospheres can have high concentrations of particulate organic carbon (oC) but the rate and fate oC deposition in near-urban ecosystems are rarely quantified. We collected atmospheric particulate matter in Phoenix, AZ and applied these samples to Sonoran Desert soils in a series of laboratory incubation experiments. The addition of fine particulate matter (<2.5 μm aerodynamic diameter) increased microbial respiration in soils collected from the interspaces between desert shrubs. The increase in soil respiration was equivalent to 25% to 30% of the added oC. In contrast, we did not detect increases in respiration when coarse particulate matter (>2.5 μm aerodynamic diameter) was added to interspace soils, suggesting that coarse particulate oC is recalcitrant to microbial decomposition. Due to comparatively higher background levels of C mineralization, we rarely detected changes in microbial respiration when fine or coarse particulate oC was added to soils collected beneath shrub canopies. We measured total atmospheric C concentrations within and surrounding Phoenix and, using inferential methods, estimated rates of deposition that ranged from 0.02 to 0.58 mg C m−2 d−1 for fine particles and from 0 to 6.15 mg C m−2 d−1 for coarse particles. Results show that fine atmospheric particulate matter deposited at low rates downwind of Phoenix is a labile oC substrate for soil heterotrophs. In contrast, oC deposited at higher rates as coarse particulate matter may accumulate in soils due to slow microbial decomposition rates.
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