Mercury transport and methylmercury production in the lower Cedar River (Iowa) floodplain

A. M. Graham, Seth Van Helten, Austin Wadle, Emily Mamrak, Jacob Morsch, Samuel F. Lopez, K. Smith
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引用次数: 1

Abstract

Scant attention has been paid to cycling of total mercury (THg) and methylmercury (MeHg) in agriculturally intensive watersheds. Monitoring of Hg and MeHg in river basins provides valuable information on the efficacy of environmental policy and the impacts of land use and climate change on Hg fluxes and biogeochemistry. We report on Hg and MeHg yields in the Cedar River (Iowa), a major tributary of the Upper Mississippi River, and on Hg biogeochemistry in a floodplain of the lower Cedar River, with emphasis on Hg cycling in groundwater and wetland ponds. For the period 2016 to 2018, total Hg yields for the 21,000 km2 Cedar River watershed ranged from 2.6 to 6.9 μg m−2 yr−1, or 25% to 70% of estimated wet deposition, and MeHg yields ranged from 0.09 to 0.18 μg m−2 yr−1. High watershed transfer efficiencies for THg are driven by soil erosion and suspended sediment delivery. Policies and land management practices targeting soil conservation are thus likely to have significant impacts on downstream transport of Hg. Within alluvial groundwaters, Hg and MeHg concentrations were highly spatiotemporally variable, ranging from 0.5 to 2.0 ng/L for THg and 0.03–1.50 ng/L for MeHg. Microtopography exerted strong control on groundwater geochemistry and Hg biogeochemical cycling, with groundwater sampled from lower lying swales exhibiting less dissolved oxygen (DO), higher conductivity, higher dissolved organic carbon (DOC), and higher THg and MeHg. The alluvial aquifer exhibits high hydrologic connectivity with the river and groundwater THg and MeHg concentrations responded rapidly to hydrologic events, with MeHg concentrations increasing with a rising water table. Concentrations of THg and MeHg in wetland ponds were elevated compared to groundwater and most strongly correlated with DOC and UV-absorbance. Methylation potentials in pond sediments were among the highest reported for freshwater sediments, up to 0.15 d−1, which we hypothesize to be linked to high primary productivity associated with nutrient enrichment. Floodplain groundwaters and wetlands constitute important ecosystem control points for downstream MeHg delivery, the magnitude of which is sensitive to changing hydroclimate, especially flood frequency.
雪松河下游(爱荷华州)洪泛平原的汞运输和甲基汞生产
在农业密集型流域,总汞(THg)和甲基汞(MeHg)的循环一直受到关注。对河流流域中汞和甲基汞的监测提供了关于环境政策效力以及土地利用和气候变化对汞通量和生物地球化学的影响的宝贵信息。我们报告了密西西比河上游主要支流雪松河(爱荷华州)的汞和甲基汞产量,以及雪松河下游泛滥平原的汞生物地球化学,重点是地下水和湿地池塘中的汞循环。2016年至2018年期间,21000平方公里雪松河流域的总汞产量在2.6至6.9μg m−2 yr−1之间,或估计湿沉降的25%至70%,甲基汞产量在0.09至0.18μg m–2 yr–1之间。THg的高流域转移效率是由土壤侵蚀和悬浮泥沙输送驱动的。因此,以土壤保护为目标的政策和土地管理做法可能对汞的下游运输产生重大影响。在冲积地下水中,汞和甲基汞的浓度具有高度的时空变化性,THg为0.5至2.0纳克/升,甲基汞为0.03至1.50纳克/升。微观地形对地下水地球化学和汞的生物地球化学循环有很强的控制作用,从地势较低的洼地取样的地下水表现出较少的溶解氧(DO)、较高的电导率、较高的溶解有机碳(DOC)以及较高的THg和MeHg。冲积含水层与河流具有高度的水文连通性,地下水THg和甲基汞浓度对水文事件反应迅速,甲基汞浓度随着地下水位的上升而增加。与地下水相比,湿地池塘中的THg和甲基汞浓度升高,并且与DOC和紫外线吸收率相关性最强。池塘沉积物中的甲基化潜力是淡水沉积物中报告的最高潜力之一,高达0.15 d−1,我们假设这与营养富集相关的高初级生产力有关。洪泛平原地下水和湿地是向下游输送甲基汞的重要生态系统控制点,其规模对不断变化的水文气候,特别是洪水频率很敏感。
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