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1998年至2018年间,通过缅因湾北大西洋时间序列(GNATS)测量的缅因湾水文、生物地球化学和酸化特性的变化

Changing Hydrographic, Biogeochemical, and Acidification Properties in the Gulf of Maine as Measured by the Gulf of Maine North Atlantic Time Series, GNATS, Between 1998 and 2018.

作者信息

Balch William M, Drapeau David T, Bowler Bruce C, Record Nicholas R, Bates Nicholas R, Pinkham Sunny, Garley Rebecca, Mitchell Catherine

机构信息

Bigelow Laboratory for Ocean Sciences East Boothbay ME USA.

Bermuda Institute of Ocean Sciences St. George Bermuda.

出版信息

J Geophys Res Biogeosci. 2022 Jun;127(6):e2022JG006790. doi: 10.1029/2022JG006790. Epub 2022 Jun 7.

DOI:10.1029/2022JG006790
PMID:35865236
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9287075/
Abstract

The Gulf of Maine North Atlantic Time Series (GNATS) has been run since 1998, across the Gulf of Maine (GoM), between Maine and Nova Scotia. GNATS goals are to provide ocean color satellite validation and to examine change in this coastal ecosystem. We have sampled hydrographical, biological, chemical, biogeochemical, and bio-optical variables. After 2008, warm water intrusions (likely North Atlantic Slope Water [NASW]) were observed in the eastern GoM at 50-180 m depths. Shallow waters (<50 m) significantly warmed in winter, summer, and fall but during spring. Surface salinity and density of the GoM also significantly increased over the 20 years. Phytoplankton standing stock and primary production showed highly-significant decreases during the period. Concentrations of phosphate increased, silicate decreased, residual nitrate [N*; nitrate-silicate] increased, and the ratio of dissolved inorganic nitrogen:phosphate decreased, suggesting increasing nitrogen limitation. Dissolved organic carbon (DOC) and its optical indices generally increased over two decades, suggesting changes to the DOC cycle. Surface seawater carbonate chemistry showed winter periods where the aragonite saturation (Ω) dropped below 1.6 gulf-wide due to upward winter mixing of cool, corrosive water. However, associated with increased average GoM temperatures, Ω has significantly increased. These results reinforce the hypothesis that the observed decrease in surface GoM primary production resulted from a switch from Labrador Sea Water to NASW entering the GoM. A multifactor analysis shows that decreasing GoM primary production is most significantly correlated to decreases in chlorophyll and particulate organic carbon plus increases in N* and temperature.

摘要

缅因湾北大西洋时间序列(GNATS)自1998年起运行,跨越缅因湾,位于缅因州和新斯科舍省之间。GNATS的目标是提供海洋颜色卫星验证,并研究这个沿海生态系统的变化。我们对水文、生物、化学、生物地球化学和生物光学变量进行了采样。2008年之后,在缅因湾东部50 - 180米深度处观测到暖水入侵(可能是北大西洋斜坡水 [NASW])。浅水区(<50米)在冬季、夏季和秋季显著变暖,但在春季并非如此。缅因湾的表层盐度和密度在这20年中也显著增加。在此期间,浮游植物现存生物量和初级生产力呈现出极显著的下降。磷酸盐浓度增加,硅酸盐浓度下降,残余硝酸盐 [N*;硝酸盐 - 硅酸盐] 增加,溶解无机氮与磷酸盐的比率下降,这表明氮限制在加剧。溶解有机碳(DOC)及其光学指数在二十年间总体上有所增加,这表明DOC循环发生了变化。表层海水碳酸盐化学性质显示,在冬季,由于凉爽、腐蚀性海水的冬季向上混合,整个海湾的文石饱和度(Ω)降至1.6以下。然而,随着缅因湾平均温度的升高,Ω显著增加。这些结果强化了这样一种假设,即缅因湾表层初级生产力的下降是由于进入缅因湾的海水从拉布拉多海水转变为NASW所致。多因素分析表明,缅因湾初级生产力的下降与叶绿素和颗粒有机碳的减少以及N*和温度的增加最为显著相关。

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