Seasonal patterns of methylmercury production, release, and degradation in profundal sediment of a hypereutrophic reservoir

IF 1.1 4区环境科学与生态学 Q4 LIMNOLOGY Lake and Reservoir Management Pub Date : 2021-07-20 DOI:10.1080/10402381.2021.1940397

B. Fuhrmann, M. Beutel, P. Ganguli, Liying Zhao, Sarah Brower, Andrew Funk, J. Pasek

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引用次数: 2

Abstract

Abstract Fuhrmann B, Beutel M, Ganguli P, Zhao L, Brower S, Funk A, Pasek J. 2021. Seasonal patterns of methylmercury production, release, and degradation in profundal sediment of a hypereutrophic reservoir. Lake Reserv Manage. 37:360–377. Profundal lake sediment is an important site of toxic methylmercury (MeHg) production by anaerobic bacteria. This study tracked sediment MeHg cycling in hypereutrophic Hodges Reservoir, in the United States. Sediment-associated MeHg was most elevated in the early spring during moderately reduced conditions. In the late spring, MeHg and iron were released into hypolimnetic water during the progression from iron-reducing to sulfate-reducing conditions at the sediment–water interface. A decrease in porewater sulfate in the early summer indicated enhanced sulfate-reducing bacteria (SRB) activity and was associated with sediment buildup of MeHg, likely due to enhanced sorption to iron sulfides. Depletion of sulfate in the sediment during the fall corresponded with a substantial decrease in both sediment and water-column MeHg, suggesting that methanogenic conditions led to enhanced MeHg degradation. Shortly afterward, MeHg increased in the hypolimnion, indicating an upward shift in the zone of SRB methylation. Our study suggests 2 “hot moments” of MeHg entry into the water column, where it is susceptible to uptake into the pelagic food web: a spring window of mildly reduced conditions that promote MeHg release from sediment, and a fall window where MeHg is produced in the upper hypolimnion. These hot moments may potentially be managed to lower mercury bioaccumulation via redox enhancement of the profundal zone with approaches such as bottom water oxygenation, which began operation in Hodges Reservoir in 2020. However, the complexity of biogeochemical responses to such management perturbations in regard to MeHg cycling makes it difficult to predict the ultimate effect of oxygenation on mercury bioaccumulation. Supplemental data for this article is available online at https://doi.org/10.1080/10402381.2021.1940397 .

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超富营养水库深层沉积物中甲基汞产生、释放和降解的季节模式

Fuhrmann B, Beutel M, Ganguli P, Zhao L, Brower S, Funk A, Pasek J. 2021。超富营养化水库深层沉积物中甲基汞产生、释放和降解的季节模式湖泊保护区管理。37:36 - 377。深层湖泊沉积物是厌氧细菌产生有毒甲基汞(MeHg)的重要场所。本研究追踪了美国富营养化霍奇斯水库沉积物中甲基汞的循环。与沉积物相关的甲基汞在初春适度减少的条件下升高最多。春末，在沉积物-水界面由铁还原向硫酸盐还原的过程中，MeHg和铁被释放到低代谢水体中。初夏孔隙水中硫酸盐的减少表明硫酸盐还原细菌(SRB)活性增强，并与甲基汞的沉积有关，可能是由于对硫化铁的吸附增强。秋季沉积物中硫酸盐的消耗与沉积物和水柱中MeHg的大幅减少相对应，表明产甲烷条件导致MeHg降解增强。不久之后，甲基汞在低磷离子中升高，表明SRB甲基化区向上移动。我们的研究表明，MeHg进入水柱的两个“热时刻”很容易被吸收到远洋食物网中:一个春季窗口，轻度减少的条件促进了MeHg从沉积物中释放，一个秋季窗口，MeHg在上层低铵离子中产生。这些热时刻可能会通过底层水氧化等方法通过深层区氧化还原增强来降低汞的生物积累，这些方法于2020年开始在霍奇斯水库运行。然而，生物地球化学对MeHg循环管理扰动的响应的复杂性使得很难预测氧化对汞生物积累的最终影响。本文的补充数据可在https://doi.org/10.1080/10402381.2021.1940397上在线获得。

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Lake and Reservoir Management 环境科学-海洋与淡水生物学

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6.70%

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期刊介绍： Lake and Reservoir Management (LRM) publishes original, previously unpublished studies relevant to lake and reservoir management. Papers address the management of lakes and reservoirs, their watersheds and tributaries, along with the limnology and ecology needed for sound management of these systems. Case studies that advance the science of lake management or confirm important management concepts are appropriate as long as there is clearly described management significance. Papers on economic, social, regulatory and policy aspects of lake management are also welcome with appropriate supporting data and management implications. Literature syntheses and papers developing a conceptual foundation of lake and watershed ecology will be considered for publication, but there needs to be clear emphasis on management implications. Modeling papers will be considered where the model is properly verified but it is also highly preferable that management based on the model has been taken and results have been documented. Application of known models to yet another system without a clear advance in resultant management are unlikely to be accepted. Shorter notes that convey important early results of long-term studies or provide data relating to causative agents or management approaches that warrant further study are acceptable even if the story is not yet complete. All submissions are subject to peer review to assure relevance and reliability for management application.