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多参数监测揭示西北地中海固定站位海岸水域阶梯式变暖

Stepped Coastal Water Warming Revealed by Multiparametric Monitoring at NW Mediterranean Fixed Stations.

机构信息

Instituto de Ciencias del Mar - CSIC, 08003 Barcelona, Spain.

Centro de Estudios Avanzados de Blanes - CSIC, 17300 Blanes, Spain.

出版信息

Sensors (Basel). 2020 May 6;20(9):2658. doi: 10.3390/s20092658.

DOI:10.3390/s20092658
PMID:32384795
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7248696/
Abstract

Since 2014, the global land and sea surface temperature has scaled 0.23 °C above the decadal average (2009-2018). Reports indicate that Mediterranean Sea temperatures have been rising at faster rates than in the global ocean. Oceanographic time series of physical and biogeochemical data collected from an onboard and a multisensor mooring array in the northwestern Mediterranean Sea (Blanes submarine canyon, Balearic Sea) during 2009-2018 revealed an abrupt temperature rising since 2014, in line with regional and global warming. Since 2014, the oligotrophic conditions of the water column have intensified, with temperature increasing 0.61 °C on the surface and 0.47 °C in the whole water column in continental shelf waters. Water transparency has increased due to a decrease in turbidity anomaly of -0.1 FTU. Since 2013, inshore chlorophyll concentration remained below the average (-0.15 mg·l) and silicates showed a declining trend. The mixed layer depth showed deepening in winter and remained steady in summer. The net surface heat fluxes did not show any trend linked to the local warming, probably due to the influence of incoming offshore waters produced by the interaction between the Northern Current and the submarine canyon. Present regional and global water heating pattern is increasing the stress of highly diverse coastal ecosystems at unprecedented levels, as reported by the literature. The strengthening of the oligotrophic conditions in the study area may also apply as a cautionary warning to similar coastal ecosystems around the world following the global warming trend.

摘要

自 2014 年以来,全球陆地和海洋表面温度比十年平均值(2009-2018 年)高出 0.23°C。报告显示,地中海的温度上升速度比全球海洋更快。2009-2018 年期间,在西北地中海(巴利阿里海的布兰卡次海峡谷)的船上和多传感器系泊阵列上收集的海洋物理和生物地球化学时间序列数据显示,自 2014 年以来,温度突然上升,与区域和全球变暖一致。自 2014 年以来,水柱的贫营养条件加剧,表层温度升高 0.61°C,大陆架水域整个水柱温度升高 0.47°C。水透明度因浊度异常减少 0.1 FTU 而增加。自 2013 年以来,近岸叶绿素浓度一直低于平均值(-0.15 毫克/升),硅酸盐呈下降趋势。混合层深度在冬季加深,夏季保持稳定。净表面热通量没有显示出与当地变暖相关的任何趋势,这可能是由于北流和次海峡谷之间相互作用产生的近海来水的影响。正如文献所报道的,目前区域和全球水加热模式正在以前所未有的水平增加高度多样化沿海生态系统的压力。研究区域贫营养条件的加强也可能对全球变暖趋势下世界范围内类似的沿海生态系统发出警告。

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本文引用的文献

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2
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Nat Ecol Evol. 2020 Feb;4(2):181-192. doi: 10.1038/s41559-019-1091-z. Epub 2020 Feb 3.
3
New High-Tech Flexible Networks for the Monitoring of Deep-Sea Ecosystems.新型高科技灵活网络,用于深海生态系统监测。
评估海洋连通性过程时间变异性的指标:一种半理论方法。
PLoS One. 2024 Jul 1;19(7):e0297730. doi: 10.1371/journal.pone.0297730. eCollection 2024.
4
Holobiont responses of mesophotic precious red coral Corallium rubrum to thermal anomalies.中光层珍稀红珊瑚红珊瑚对热异常的共生体反应。
Environ Microbiome. 2023 Aug 14;18(1):70. doi: 10.1186/s40793-023-00525-6.
Environ Sci Technol. 2019 Jun 18;53(12):6616-6631. doi: 10.1021/acs.est.9b00409. Epub 2019 Jun 5.
4
How fast are the oceans warming?海洋变暖的速度有多快?
Science. 2019 Jan 11;363(6423):128-129. doi: 10.1126/science.aav7619.
5
Impacts of warming on phytoplankton abundance and phenology in a typical tropical marine ecosystem.变暖对典型热带海洋生态系统中浮游植物丰度和物候的影响。
Sci Rep. 2018 Feb 2;8(1):2240. doi: 10.1038/s41598-018-20560-5.
6
The Oceanic Biological Pump: Rapid carbon transfer to depth at Continental Margins during Winter.海洋生物泵:冬季大陆边缘的快速碳向深层转移。
Sci Rep. 2017 Sep 7;7(1):10763. doi: 10.1038/s41598-017-11075-6.
7
An ecosystem-based deep-ocean strategy.基于生态系统的深海战略。
Science. 2017 Feb 3;355(6324):452-454. doi: 10.1126/science.aah7178.
8
Abrupt climate shift in the Western Mediterranean Sea.西地中海地区的气候突变。
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9
Mass Mortality Events in the NW Adriatic Sea: Phase Shift from Slow- to Fast-Growing Organisms.亚得里亚海西北部的大规模死亡事件:从生长缓慢的生物到生长快速的生物的阶段性转变。
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10
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