利用 234Th238U 的不平衡计算中太平洋的颗粒汞输出

IF 3 3区 地球科学 Q2 CHEMISTRY, MULTIDISCIPLINARY
Blaire P. Umhau , Laura C. Motta , Joel D. Blum , Hilary G. Close , Jeffrey C. Drazen , Brian N. Popp , Claudia R. Benitez-Nelson
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引用次数: 0

摘要

汞(Hg)是一种强效神经毒素,可进入食物网,污染商业鱼类、休闲鱼类、生计鱼类和祭祀鱼类。因此,了解这种污染在海洋系统中发生的途径是最大限度降低消费者健康风险的重要组成部分。然而,我们对汞的生物地球化学循环的了解还相对有限。我们在北太平洋亚热带环流(NPSG)中的 ALOHA 站(北纬 22°,西经 158°),沿南北横断面至赤道(北纬 17.5°至北纬 5°x西经 155°),采用原位泵和铀-238/钍-234 不平衡作为微粒输出的示踪剂,对整个上 400 米沉降微粒汞通量的时间变化进行了研究。我们的研究结果表明,ALOHA 站的 PHg 出口通量随季节变化,最高通量出现在 5 月份(175 米,346 pmol m-2 day-1),此时正值夏季浮游动物生长期;最高通量出现在 9 月份(400 米,356 pmol m-2 day-1),此时正值重氮营养盐介导的夏季出口脉冲期。5 月和 9 月的 PHg 通量高于以前在赤道太平洋 150 米处测得的通量,并在 400 米处持续较高(100 pmol Hg m-2 d-1),从而为中层食物网提供了重要的汞来源。与 ALOHA 站不同的是,在北纬 8 度和 5 度,PHg 通量随深度的增加而迅速减弱,通量普遍较低,最大通量为 86 pmol m-2 d-1(北纬 5 度)。北纬 8 度和 5 度的深度剖面差异显著,北纬 5 度整个水体的 PHg 通量较高,其特点是次表层的汞通量峰值比北纬 8 度高 3 倍(86 对 29 pmol Hg m-2 d-1)。单甲基汞(MeHg)通量(最大值 = 1.09 ± 0.57 pmol m-2 d-1)和浓度(最大值 = 0.14 fmol L-1)仅占 PHg 总量的一小部分。这些结果表明,至少在厄尔尼诺年期间,PHg 循环在北太平洋和赤道附近有显著差异。在 ALOHA 站,深层叶绿素最高值以下的小颗粒物的微生物再加工与浮游动物捕食的变化推动了季节性出口变化。与此相反,在赤道附近,由于生物生产率低,PHg 向深层迁移的通量也低,在厄尔尼诺年期间,PHg 向深层迁移的通量明显降低。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Particulate mercury export in the Central Pacific Ocean using 234Th238U disequilibria

Mercury (Hg) is a potent neurotoxin that enters the food web and may contaminate commercial, recreational, subsistence, and ceremonial fish stocks. Understanding the pathways by which this contamination occurs in marine systems is thus an essential component of minimizing consumer health risk. Our knowledge of the biogeochemical cycling of mercury, however, is relatively limited. Temporal changes in sinking particulate mercury (PHg) fluxes throughout the upper 400 m were examined at Station ALOHA (22°N, 158°W) in the North Pacific Subtropical Gyre (NPSG) and spatially along a north-south transect to the Equator (17.5°N to 5°N x 155°W) using a combination of in situ pumps and Uranium-238/Thorium-234 disequilibria as a tracer of particle export. Our results indicate that Station ALOHA is characterized by seasonally variable export fluxes of PHg, with highest fluxes occurring in May (175 m, 346 pmol m−2 day−1), with the advent of summer zooplankton growth, and in September (400 m, 356 pmol m−2 day−1), coinciding with a diazotroph mediated summer export pulse. PHg fluxes in May and September were higher than those previously measured in the equatorial Pacific at 150 m and continued to be high (> 100 pmol Hg m−2 d−1) down to 400 m, thereby providing a significant source of Hg to the mesopelagic food web. In contrast to Station ALOHA, at 8 and 5°N, PHg fluxes attenuated rapidly with depth, and fluxes were generally lower, with a maximum flux of 86 pmol m−2 d−1 (5°N). Depth profiles at 8 and 5°N were significantly different from one another, with PHg fluxes higher throughout the water column at 5°N and characterized by a subsurface peak in Hg flux 3 times higher than at 8°N (86 vs. 29 pmol Hg m−2 d−1). Monomethylmercury (MeHg) fluxes (max = 1.09 ± 0.57 pmol m−2 d−1) and concentrations (max = 0.14 fmol L−1) comprised only a small percentage of the total PHg pool. These results suggest that PHg cycling significantly differed between the NPSG and near the equator at least during an El Niño year. At Station ALOHA, microbial reworking of small particles below the deep chlorophyll maximum coupled with changes in zooplankton grazing drive seasonal export variability. In contrast near the equator, low fluxes associated with low biological productivity result in significantly lower PHg transport to depth during an El Niño year.

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来源期刊
Marine Chemistry
Marine Chemistry 化学-海洋学
CiteScore
6.00
自引率
3.30%
发文量
70
审稿时长
4.5 months
期刊介绍: Marine Chemistry is an international medium for the publication of original studies and occasional reviews in the field of chemistry in the marine environment, with emphasis on the dynamic approach. The journal endeavours to cover all aspects, from chemical processes to theoretical and experimental work, and, by providing a central channel of communication, to speed the flow of information in this relatively new and rapidly expanding discipline.
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