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Gill, Allison L.; Adler, Peter B.; Borer, Elizabeth T.; Buyarski, Christopher R.; Cleland, Elsa E.; D'Antonio, Carla M.; Davies, Kendi F.; Gruner, Daniel S.; Harpole, W. Stanley; Hofmockel, Kirsten S.; MacDougall, Andrew S.; McCulley, Rebecca L.; Melbourne, Brett A.; Moore, Joslin L.; Morgan, John W.; Risch, Anita C.; Schütz, Martin; Seabloom, Eric W.; Wright, Justin P.; Yang, Louie H.; Hobbie, Sarah E.
The Journal of ecology, June 2022, 2022-06-00, 20220601, Volume: 110, Issue: 6Journal Article
To evaluate how increased anthropogenic nutrient inputs alter carbon cycling in grasslands, we conducted a litter decomposition study across 20 temperate grasslands on three continents within the Nutrient Network, a globally distributed nutrient enrichment experiment We determined the effects of addition of experimental nitrogen (N), phosphorus (P) and potassium plus micronutrient (Kμ) on decomposition of a common tree leaf litter in a long‐term study (maximum of 7 years; exact deployment period varied across sites). The use of higher order decomposition models allowed us to distinguish between the effects of nutrients on early‐ versus late‐stage decomposition. Across continents, the addition of N (but not other nutrients) accelerated early‐stage decomposition and slowed late‐stage decomposition, increasing the slowly decomposing fraction by 28% and the overall litter mean residence time by 58%. Synthesis. Using a novel, long‐term cross‐site experiment, we found widespread evidence that N enhances the early stages of above‐ground plant litter decomposition across diverse and widespread temperate grassland sites but slows late‐stage decomposition. These findings were corroborated by fitting the data to multiple decomposition models and have implications for N effects on soil organic matter formation. For example, following N enrichment, increased microbial processing of litter substrates early in decomposition could promote the production and transfer of low molecular weight compounds to soils and potentially enhance the stabilization of mineral‐associated organic matter. By contrast, by slowing late‐stage decomposition, N enrichment could promote particulate organic matter (POM) accumulation. Such hypotheses deserve further testing. In a long‐term experiment across 20 diverse and widespread temperate grassland sites, nitrogen enhanced the early stages of aboveground plant litter decomposition, accelerating the initial decay rate, ka, and reducing the time to 10% mass loss, t1/10, but slowed late‐stage decomposition, increasing the mean residence time, MRT, and fraction of slowly decomposing litter, asymptotic A.
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