EcoLab, Université de Toulouse, CNRS, INPT, UPS, Toulouse, France.
EcoLab, Université de Toulouse, CNRS, INPT, UPS, Toulouse, France.
Water Res. 2019 Jul 1;158:118-135. doi: 10.1016/j.watres.2019.04.018. Epub 2019 Apr 12.
The export of organic carbon export by the rivers to the oceans either as particulate organic carbon (POC) or dissolved organic carbon (DOC) is very sensitive to climate change especially in permafrost affected catchments where soils are very rich in organic carbon. With global warming, organic carbon export in both forms is expected to increase in Arctic regions. It should affect contemporary biogeochemical cycles in rivers and oceans and therefore modify the whole food web. This study tries to understand complex processes involved in sediment, POC and DOC riverine transport in the Yenisei River basin and to quantify their respective fluxes at the river outlet. The SWAT (Soil and Water Assessment Tool) hydrological model is used in this study to simulate water and suspended sediment transfers in the largest Arctic river. POC and DOC export have been quantified with empirical models, adapted from literature for the study case. First, the hydrological model has been calibrated and validated at a daily time step for the 2003-2008 and the 2009-2016 periods respectively, and its output has been compared with field data for water and sediment fluxes. Based on conceptualization of transfer processes, calibration on climate and soil properties has been performed in order to correctly represent hydrology and sediment transfer in permafrost basins. Second, calibration of empirical models for DOC/POC transport have been performed by comparing their output with field data, available from 2003 to 2016. Our study reveals that SWAT is capable of correctly representing hydrology, sediment transfer, POC and DOC fluxes and their spatial distribution at a daily timescale, and outlines the links between these fluxes and permafrost features. Our simulation effort results in specific sediment, POC and DOC fluxes of 2.97 t km yr, 0.13 t km yr and 1.14 t km yr for the period 2003-2016 which are in the range of previous estimates. About 60% of the total fluxes of sediment, DOC and POC to the Arctic Ocean are exported during the two months of the freshet. Spatial analysis show that permafrost-free areas have returned higher daily organic carbon export than permafrost affected zones, highlighting the thawing permafrost effect on carbon cycle in climate change feedback.
河流向海洋输送的有机碳(包括颗粒态有机碳(POC)和溶解态有机碳(DOC))对气候变化非常敏感,特别是在富含有机碳的多年冻土地区。随着全球变暖,北极地区两种形式的有机碳输出预计都会增加。这将影响河流和海洋中的当代生物地球化学循环,并因此改变整个食物网。本研究旨在了解叶尼塞河流域泥沙、POC 和 DOC 河流输运过程中的复杂过程,并定量估算河流出口处的有机碳通量。本研究采用 SWAT(土壤和水评估工具)水文模型模拟最大的北极河流的水和悬移质泥沙转移。利用文献中的经验模型来估算 POC 和 DOC 的输出,该模型适用于研究案例。首先,分别对 2003-2008 年和 2009-2016 年进行了每日时间步长的水文模型校准和验证,并将模型输出与水和泥沙通量的现场数据进行了比较。基于传输过程的概念化,对气候和土壤特性进行了校准,以正确表示多年冻土流域的水文和泥沙传输。其次,通过将输出与 2003-2016 年的现场数据进行比较,对 DOC/POC 传输的经验模型进行了校准。我们的研究表明,SWAT 能够在每日时间尺度上正确地表示水文、泥沙转移、POC 和 DOC 通量及其空间分布,并概述了这些通量与多年冻土特征之间的联系。我们的模拟结果表明,2003-2016 年期间,泥沙、POC 和 DOC 的特定通量分别为 2.97 t km yr、0.13 t km yr 和 1.14 t km yr,这与之前的估计值在同一范围内。在洪水期的两个月中,约有 60%的泥沙、DOC 和 POC 总通量被输送到北冰洋。空间分析表明,无多年冻土区的每日有机碳输出高于多年冻土区,突出了多年冻土融化对气候变化反馈中碳循环的影响。
