Abstract
Carbon stable isotopes (δ13C) of particulate organic matter (POM) are useful indicators for tracking the sources of organic matter, CO2 concentrations, primary productivity and the trophic base in lakes. Here we provide a synthesis of literature data from 228 lakes around the world to assess the distribution pattern of δ13CPOM along latitudinal, morphometric and biogeochemical gradients, and the feasibility of utilizing δ13CPOM as an indicator for lake metabolism. Results from this analysis revealed a large variation in δ13CPOM among lakes with a range from −46.2 to −13.0‰ and a median of −29.7‰. The δ13CPOM generally decreased from low to high latitude along with the decreases in total phosphorus (TP), pH, lake size and the increases in partial pressure of CO2. The combination of these factors may play a significant role in shaping the pattern of δ13CPOM distribution. A multiple regression model using matching data (n = 92 lakes) indicated that latitude, lake size and TP concentration were the important factors determining δ13CPOM, although only 25% of the variance in δ13CPOM was explained by the model. Compared to the average δ13C value (−27‰) of terrestrial plants, 165 lakes (72%) in this analysis were isotopically depleted in δ13CPOM, with a mean of −31.5‰, which is indicative of an allochthonous contribution of terrestrial organic matter. This finding is consistent with the view that the majority of lakes in the world receive a terrestrial subsidy of carbon and are sources of CO2 to the atmosphere.
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This study was supported by the National Natural Science Foundation of China (grant nos. 31070419 and 31170441). We appreciate Dr. Thomas Dreschel for language improvements.
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Liu, D., Chen, G., Li, Y. et al. Global pattern of carbon stable isotopes of suspended particulate organic matter in lakes. Limnology 13, 253–260 (2012). https://doi.org/10.1007/s10201-011-0371-3
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DOI: https://doi.org/10.1007/s10201-011-0371-3