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横向输运和涡旋促进了城市富营养化的大规模响应。

Cross-shore transport and eddies promote large scale response to urban eutrophication.

机构信息

Department of Biogeochemistry, Southern California Coastal Water Research Project, 3535 Harbor Blvd, Suite 110, Costa Mesa, CA, 92626, USA.

Department of Atmospheric and Oceanic Sciences, University of California Los Angeles, Los Angeles, CA, 90095, USA.

出版信息

Sci Rep. 2024 Mar 27;14(1):7240. doi: 10.1038/s41598-024-57626-6.

DOI:10.1038/s41598-024-57626-6
PMID:38538671
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11350003/
Abstract

A key control on the magnitude of coastal eutrophication is the degree to which currents quickly transport nitrogen derived from human sources away from the coast to the open ocean before eutrophication develops. In the Southern California Bight (SCB), an upwelling-dominated eastern boundary current ecosystem, anthropogenic nitrogen inputs increase algal productivity and cause subsurface acidification and oxygen (O ) loss along the coast. However, the extent of anthropogenic influence on eutrophication beyond the coastal band, and the physical transport mechanisms and biogeochemical processes responsible for these effects are still poorly understood. Here, we use a submesoscale-resolving numerical model to document the detailed biogeochemical mass balance of nitrogen, carbon and oxygen, their physical transport, and effects on offshore habitats. Despite management of terrestrial nutrients that has occurred in the region over the last 20 years, coastal eutrophication continues to persist. The input of anthropogenic nutrients promote an increase in productivity, remineralization and respiration offshore, with recurrent O loss and pH decline in a region located 30-90 km from the mainland. During 2013 to 2017, the spatially averaged 5-year loss rate across the Bight was 1.3 mmol m O , with some locations losing on average up to 14.2 mmol m O . The magnitude of loss is greater than model uncertainty assessed from data-model comparisons and from quantification of intrinsic variability. This phenomenon persists for 4 to 6 months of the year over an area of 278,40 km ( 30% of SCB area). These recurrent features of acidification and oxygen loss are associated with cross-shore transport of nutrients by eddies and plankton biomass and their accumulation and retention within persistent eddies offshore within the SCB.

摘要

沿海富营养化程度的一个关键控制因素是,在富营养化发展之前,海流将源自人类的氮素迅速输送到远离海岸的开阔海域的程度。在南加州湾(SCB),一个上升流主导的东部边界海流生态系统中,人为氮素输入增加了藻类生产力,并导致沿海地区的次表层酸化和氧气(O 2 )损失。然而,人为因素对沿海带以外富营养化的影响程度,以及负责这些影响的物理输运机制和生物地球化学过程仍知之甚少。在这里,我们使用亚网格分辨率数值模型来记录氮、碳和氧的详细生物地球化学质量平衡、它们的物理输运以及对近海生境的影响。尽管该地区在过去 20 年里对陆地养分进行了管理,但沿海富营养化仍在持续。人为养分的输入促进了生产力的增加、近海的再矿化和呼吸作用,在距大陆 30-90 公里的区域,反复出现氧气损失和 pH 值下降。在 2013 年至 2017 年期间,整个湾区的空间平均 5 年损失率为 1.3mmol m O 2 ,有些地点的平均损失率高达 14.2mmol m O 2 。损失的幅度大于从数据-模型比较和对固有变异性的量化中评估的模型不确定性。这种现象在 SCB 地区 278,40 平方公里(占 SCB 面积的 30%)的区域内,每年持续 4 到 6 个月。这种酸化和氧气损失的反复出现的特征与由涡流和浮游生物生物量引起的营养物质的横向输运以及在 SCB 近海的持久涡流中它们的积累和滞留有关。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c33a/11350003/1116cdd7677a/41598_2024_57626_Fig11_HTML.jpg
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