COS 44-5 - Mobilization of silica in terrestrial grassland ecosystems and the potential impact on the global silica cycle

Tuesday, August 5, 2008: 2:50 PM
101 B, Midwest Airlines Center
E.F. Kelly1, A.K. Knapp2, S.W. Blecker3, S. E. Melzer4, Rebecca L. McCulley5, C.M. Yonker4, O.a. Chadwick6, Melinda Smith2, John Blair7, K. Kirkman8 and Alan Knapp9, (1)Department of Biology, Colorado State University, Fort Collins, CO, (2)Graduate Degree Program in Ecology, Colorado State University, Fort Collins, CO, (3)Water Resources, U.S. Geological Survey, Reno, NV, (4)Soil and Crop Sciences, Colorado State University, Fort Collins, CO, (5)Plant & Soil Sciences, University of Kentucky, Lexington, KY, (6)Geography, University of California, Santa Barbara, CA, (7)Biology, Kansas State University, Manhattan, KS, (8)Grassland Science, School of Biological and Conservation Sciences, University of KwaZulu-Natal, Pietermaritzburg, South Africa, (9)Scientific Services, Kruger National Park, Skukuza, 1350, South Africa
Background/Question/Methods The biogeochemical behavior of silica is closely linked to that of other important elements and in particular si biogeochemistry may strongly impact the carbon cycle.  This is well-documented in marine systems where diatoms are a major control on the distribution of silica in the oceans, and play a major role in controlling atmospheric pCO2 via the “biological pump”. However, the importance of biological and ecological controls on silica cycling in the terrestrial environment is much less well known, despite the fact that the source of marine si is terrestrial.. The primary goal of our research is to better quantify the pool size of Biogenic Silica (BSi) in grasslands and begin to identify the ecological controls of BSi above and belowground. We quantified the biogeochemistry of biogenic silica along bioclimatic and geologic gradients in grass dominated ecosystems worldwide. Our results are based on intensive field investigations and modeled results from grassland production data. We have identified the possible effects of biogeographically diverse grassland ecosystems on the production, storage, and geochemical behavior of BSi,  a requisite first step in forecasting global change impacts on the linkages between terrestrial and marine Si cycles.
Results/Conclusions Our estimates for aboveground BSi in the biomass in North American grasslands alone are approximately 0.3 Tmol Si.  Of greater importance however is our estimate of the storage of BSi in grassland soils, which is roughly 130 Tmol of Si.  Our results demonstrate that the BSi stored in the soils of temperate grassland ecosystems alone rival the estimated global storage in biomass and is almost half of what is stored in the ocean. The importance of terrestrial Si and its export to marine systems is similar to Iron (Fe), which also has its major source on land and is considered a critical limiting element in marine systems.  The literature reports that approximately 10 Tmol of Si is delivered to oceans via dust, and our first order assessment of North American grasslands suggests that dust export could be as high as 60 to 100 Tmol. This is a significant fraction of the BSi stored in the ocean - estimated to be 240 Tmol – and suggests that a strong link exists between global grassland productivity and marine C cycles.
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