暗减驱动水星从海洋中逃逸

C. Lamborg, C. Hansel, K. Bowman, B. Voelker, R. Marsico, V. Oldham, G. Swarr, Tong Zhang, P. Ganguli
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引用次数: 8

摘要

相对于大气,海洋的大部分地表水的元素汞(Hg0)过饱和,导致海洋向空气转移或逃逸。这种通量很大,几乎平衡了来自大气、河流和热液喷口的输入。虽然从离子汞和甲基化汞光化学产生Hg0的研究相当充分,并且可以以相当高的速率产生HgO,但在无公害水中也存在丰富的Hg0,这表明存在其他重要的形成途径。在这里,我们介绍了总还原率测量、深度剖面和电介质循环研究的结果,以证明Hg2+的暗还原也能够维持公海混合层中的Hg0浓度。在垂直混合相对于UV-B和光合活性辐射(参与非生物和生物汞光还原的主要光形式)的垂直穿透足够深的位置,暗还原将贡献表层海洋混合层中产生的大部分Hg0。我们的测量和建模表明,除了当地夏季的高纬度地区外,几乎所有地方都符合这些条件。此外,Hg0在混合层中相对于逃逸的停留时间比氧化还原的停留时间长,这种情况允许暗还原氧化有效地设定地表水中Hg0与Hg2+的稳态比率。这项研究没有解决海洋中这些黑暗氧化还原反应的性质,但我们的实验表明,可能存在一种或多种机制,涉及酶和/或重要的氧化还原剂,如活性氧和锰(III)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dark Reduction Drives Evasion of Mercury From the Ocean
Much of the surface water of the ocean is supersaturated in elemental mercury (Hg0) with respect to the atmosphere, leading to sea-to-air transfer or evasion. This flux is large, and nearly balances inputs from the atmosphere, rivers and hydrothermal vents. While the photochemical production of Hg0 from ionic and methylated mercury is reasonably well-studied and can produce Hg0 at fairly high rates, there is also abundant Hg0 in aphotic waters, indicating that other important formation pathways exist. Here, we present results of gross reduction rate measurements, depth profiles and diel cycling studies to argue that dark reduction of Hg2+ is also capable of sustaining Hg0 concentrations in the open ocean mixed layer. In locations where vertical mixing is deep enough relative to the vertical penetration of UV-B and photosynthetically active radiation (the principal forms of light involved in abiotic and biotic Hg photoreduction), dark reduction will contribute the majority of Hg0 produced in the surface ocean mixed layer. Our measurements and modeling suggest that these conditions are met nearly everywhere except at high latitudes during local summer. Furthermore, the residence time of Hg0 in the mixed layer with respect to evasion is longer than that of redox, a situation that allows dark reduction-oxidation to effectively set the steady-state ratio of Hg0 to Hg2+ in surface waters. The nature of these dark redox reactions in the ocean was not resolved by this study, but our experiments suggest a likely mechanism or mechanisms involving enzymes and/or important redox agents such as reactive oxygen species and manganese (III).
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