Variability in organic carbon reactivity across lake residence time and trophic gradients

溶解有机碳 环境科学 总有机碳 碳循环 营养水平 环境化学 有机质 碳纤维 停留时间(流体动力学) 生态学 化学 生态系统 地质学 生物 复合数 复合材料 岩土工程 材料科学
作者
Chris Evans,Martyn N. Futter,Filip Moldan,Salar Valinia,Z. L. Frogbrook,Dolly N. Kothawala
出处
期刊:Nature Geoscience [Nature Portfolio]
卷期号:10 (11): 832-835 被引量:157
标识
DOI:10.1038/ngeo3051
摘要

The transport of dissolved organic carbon from land to ocean is a large dynamic component of the global carbon cycle. Inland waters are hotspots for organic matter turnover, via both biological and photochemical processes, and mediate carbon transfer between land, oceans and atmosphere. However, predicting dissolved organic carbon reactivity remains problematic. Here we present in situ dissolved organic carbon budget data from 82 predominantly European and North American water bodies with varying nutrient concentrations and water residence times ranging from one week to 700 years. We find that trophic status strongly regulates whether water bodies act as net dissolved organic carbon sources or sinks, and that rates of both dissolved organic carbon production and consumption can be predicted from water residence time. Our results suggest a dominant role of rapid light-driven removal in water bodies with a short water residence time, whereas in water bodies with longer residence times, slower biotic production and consumption processes are dominant and counterbalance one another. Eutrophication caused lakes to transition from sinks to sources of dissolved organic carbon. We conclude that rates and locations of dissolved organic carbon processing and associated CO2 emissions in inland waters may be misrepresented in global carbon budgets if temporal and spatial reactivity gradients are not accounted for. The production and consumption of organic carbon in inland waters varies with water residence time and biotic processes, suggest analyses of dissolved organic carbon from Northern Hemisphere water bodies. Inland waters mediate carbon transport between land and ocean.
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