Carbonyl sulfide exchange in soils for better estimates of ecosystem carbon uptake

• Published in: Atmospheric chemistry and physics Vol. 16; no. 6; pp. 3711 - 3726
• Main Authors: Whelan, Mary E, Hilton, Timothy W, Berry, Joseph A, Berkelhammer, Max, Desai, Ankur R, Campbell, J. Elliott
• Format: Journal Article
• Language: English
• Published: Katlenburg-Lindau Copernicus GmbH 21.03.2016; European Geosciences Union; Copernicus Publications
• Subjects: Agricultural land; Air monitoring; Atmosphere; Carbon; Carbon cycle; Carbon dioxide; Carbon uptake; Carbonyl compounds; Carbonyl sulfide; Carbonyls; Chemical properties; cos; Deciduous forests; dimethyl sulfide; Ecosystems; ENVIRONMENTAL SCIENCES; Fluxes; forest soils; gas-exchange; global budget; growing-season; Observations; organic-matter; Primary production; Rainforests; Savannahs; Soil; Soil carbon; Soil conditions; Soil investigations; Soil moisture; Soil temperature; Soils; southern great-plains; Soybeans; Sulfides; Sulphides; trace gases; Uptake; Wetlands; California; Chicago Illinois; United States > US; Illinois; Peru; Great Plains
• ISSN: 1680-7324; 1680-7316; 1680-7324
• DOI: 10.5194/acp-16-3711-2016

Carbonyl sulfide (COS) measurements are one of the emerging tools to better quantify gross primary production (GPP), the largest flux in the global carbon cycle. COS is a gas with a similar structure to CO2; COS uptake is thought to be a proxy for GPP. However, soils are a potential source or sink of COS. This study presents a framework for understanding soil–COS interactions. Excluding wetlands, most of the few observations of isolated soils that have been made show small uptake of atmospheric COS. Recently, a series of studies at an agricultural site in the central United States found soil COS production under hot conditions an order of magnitude greater than fluxes at other sites. To investigate the extent of this phenomenon, soils were collected from five new sites and incubated in a variety of soil moisture and temperature states. We found that soils from a desert, an oak savannah, a deciduous forest, and a rainforest exhibited small COS fluxes, behavior resembling previous studies. However, soil from an agricultural site in Illinois,  > 800 km away from the initial central US study site, demonstrated comparably large soil fluxes under similar conditions. These new data suggest that, for the most part, soil COS interaction is negligible compared to plant uptake of COS. We present a model that anticipates the large agricultural soil fluxes so that they may be taken into account. While COS air-monitoring data are consistent with the dominance of plant uptake, improved interpretation of these data should incorporate the soil flux parameterizations suggested here.