Alice Paine, Joost Frieling, Timothy Shanahan, Tamsin Mather, Nicholas McKay, Stuart Robinson, David Pyle, Isabel Fendley, Ruth Kiely, William Gosling
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Here, we present a high-resolution sedimentary Hg record from tropical Lake Bosumtwi (Ghana, West Africa) since ~96 ka. A coupled response is observed between Hg flux and shifts in sediment composition, the latter reflecting changes in lake level. Specifically, we find that the amplitude and frequency of Hg peaks increase as the lake level rises, suggesting that Hg burial was enhanced in response to an insolation-driven increase in precipitation at ~73 ka. A more transient, threefold increase in Hg concentration and accumulation rate is also recorded between ~13 and 4 ka, coinciding with a period of distinctly higher rainfall across North Africa known as the African Humid Period. Two mechanisms, likely working in tandem, could explain this correspondence: (1) an increase in wet deposition of Hg by precipitation and (2) efficient sequestration of organic-hosted Hg. 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引用次数: 0
摘要
摘要水文的变化影响着汞(Hg)等元素的生物地球化学循环,其在环境中的迁移和转化似乎与不同时间尺度的水文气候有关。关于这些过程在不同时间尺度上的表现形式及其潜在的环境后果,仍然存在一些关键问题。例如,由于很少有沉积记录具有足够的长度和/或分辨率来记录汞循环的突然和持久变化,以及沉积过程在这些变化中的相对作用,因此人们对陆地领域千年尺度的汞-水文气候相互作用知之甚少。在这里,我们展示了自约 96 ka 年以来热带博苏姆特维湖(西非加纳)的高分辨率沉积汞记录。我们观察到汞通量与沉积物成分变化之间的耦合反应,后者反映了湖泊水位的变化。具体来说,我们发现随着湖泊水位的上升,汞峰的振幅和频率也在增加,这表明在约 73 ka 时,由于日照驱动的降水量增加,汞的埋藏量也随之增加。在约 13 至 4 ka 期间,汞浓度和积累率也出现了更短暂的三倍增长,这与整个北非降雨量明显增加的时期(即非洲湿润期)相吻合。有两种机制可以解释这种对应关系:(1) 降水造成的汞湿沉积增加;(2) 有机态汞的有效固存。总之,我们的研究结果再次证明,水文气候的变化(直接和/或间接)与热带汞循环的千年尺度变化有关,这些信号可以记录在湖泊沉积物中。
New evidence for millennial-scale interactions between Hg cycling and hydroclimate from Lake Bosumtwi, Ghana
Abstract. Changing hydrology impacts the biogeochemical cycling of elements such as mercury (Hg), whose transport and transformation in the environment appear linked to hydroclimate on diverse timescales. Key questions remain about how these processes manifest over different timescales and their potential environmental consequences. For example, millennial-scale Hg-hydroclimate interactions in the terrestrial realm are poorly understood, as few sedimentary records have sufficient length and/or resolution to record abrupt and long-lasting changes in Hg cycling, and the relative roles of depositional processes on these changes. Here, we present a high-resolution sedimentary Hg record from tropical Lake Bosumtwi (Ghana, West Africa) since ~96 ka. A coupled response is observed between Hg flux and shifts in sediment composition, the latter reflecting changes in lake level. Specifically, we find that the amplitude and frequency of Hg peaks increase as the lake level rises, suggesting that Hg burial was enhanced in response to an insolation-driven increase in precipitation at ~73 ka. A more transient, threefold increase in Hg concentration and accumulation rate is also recorded between ~13 and 4 ka, coinciding with a period of distinctly higher rainfall across North Africa known as the African Humid Period. Two mechanisms, likely working in tandem, could explain this correspondence: (1) an increase in wet deposition of Hg by precipitation and (2) efficient sequestration of organic-hosted Hg. Taken together, our results reaffirm that changes in hydroclimate, directly and/or indirectly, can be linked to millennial-scale changes in tropical Hg cycling, and that these signals can be recorded in lake sediments.
期刊介绍:
Climate of the Past (CP) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on the climate history of the Earth. CP covers all temporal scales of climate change and variability, from geological time through to multidecadal studies of the last century. Studies focusing mainly on present and future climate are not within scope.
The main subject areas are the following:
reconstructions of past climate based on instrumental and historical data as well as proxy data from marine and terrestrial (including ice) archives;
development and validation of new proxies, improvements of the precision and accuracy of proxy data;
theoretical and empirical studies of processes in and feedback mechanisms between all climate system components in relation to past climate change on all space scales and timescales;
simulation of past climate and model-based interpretation of palaeoclimate data for a better understanding of present and future climate variability and climate change.