Coastal and regional marine heatwaves and cold spells in the northeastern Atlantic

IF 4.1 3区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Ocean Science Pub Date : 2023-09-06 DOI:10.5194/os-19-1339-2023

A. Simon, Coline Poppeschi, S. Plecha, G. Charria, A. Russo

{"title":"Coastal and regional marine heatwaves and cold spells in the northeastern Atlantic","authors":"A. Simon, Coline Poppeschi, S. Plecha, G. Charria, A. Russo","doi":"10.5194/os-19-1339-2023","DOIUrl":null,"url":null,"abstract":"Abstract. The latest Intergovernmental Panel on Climate Change (IPCC) report describes an increase in the number and intensity of marine heatwaves (MHWs) and a decrease in marine cold spells (MCSs) in\nthe global ocean. However, these reported changes are not uniform on a regional to local basis, and it remains unknown if coastal areas follow the\nopen-ocean trends. Surface ocean temperature measurements collected by satellites (from 1982–2022) and 13 coastal buoys (from 1990–2022) are\nanalyzed in the northeastern Atlantic and three subregions: the English Channel, Bay of Brest and Bay of Biscay. The activity metric, combining the number\nof events, intensity, duration and spatial extent, is used to evaluate the magnitude of these extreme events. The results from in situ and\nsatellite datasets for each of the studied regions are quite in agreement, although the satellite dataset underestimates the amplitude of activity\nfor both MHWs and MCSs. This supports the applicability of the method to both in situ and satellite data, albeit with caution on the amplitude of\nthese events. Also, this localized study in European coastal northeastern Atlantic water highlights that similar changes are being seen in coastal and\nopen oceans regarding extreme events of temperature, with MHWs being more frequent and longer and extending over larger areas, while the opposite is\nseen for MCSs. These trends can be explained by changes in both the mean of and variance in sea-surface temperature. In addition, the pace of evolution\nand dynamics of marine extreme events differ among the subregions. Among the three studied subregions, the English Channel is the region\nexperiencing the strongest increase in summer MHW activity over the last 4 decades. Summer MHWs were very active in the English Channel in 2022\ndue to long events, in the Bay of Biscay in 2018 due to intense events and in the Bay of Brest in 2017 due to a high occurrence of events. Winter\nMCSs were the largest in 1987 and 1986 due to long and intense events in the English Channel. Finally, our findings suggest that at an interannual\ntimescale, the positive North Atlantic Oscillation favors the generation of strong summer MHWs in the northeastern Atlantic, while\nlow-pressure conditions over northern Europe and a high off the Iberian Peninsula in winter dominate for MCSs. A preliminary analysis of air–sea\nheat fluxes suggests that, in this region, reduced cloud coverage is a key parameter for the generation of summer MHWs, while strong winds and\nincreased cloud coverage are important for the generation of winter MCSs.\n","PeriodicalId":19535,"journal":{"name":"Ocean Science","volume":"8 1","pages":""},"PeriodicalIF":4.1000,"publicationDate":"2023-09-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Ocean Science","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.5194/os-19-1339-2023","RegionNum":3,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"METEOROLOGY & ATMOSPHERIC SCIENCES","Score":null,"Total":0}

引用次数: 0

Abstract

Abstract. The latest Intergovernmental Panel on Climate Change (IPCC) report describes an increase in the number and intensity of marine heatwaves (MHWs) and a decrease in marine cold spells (MCSs) in the global ocean. However, these reported changes are not uniform on a regional to local basis, and it remains unknown if coastal areas follow the open-ocean trends. Surface ocean temperature measurements collected by satellites (from 1982–2022) and 13 coastal buoys (from 1990–2022) are analyzed in the northeastern Atlantic and three subregions: the English Channel, Bay of Brest and Bay of Biscay. The activity metric, combining the number of events, intensity, duration and spatial extent, is used to evaluate the magnitude of these extreme events. The results from in situ and satellite datasets for each of the studied regions are quite in agreement, although the satellite dataset underestimates the amplitude of activity for both MHWs and MCSs. This supports the applicability of the method to both in situ and satellite data, albeit with caution on the amplitude of these events. Also, this localized study in European coastal northeastern Atlantic water highlights that similar changes are being seen in coastal and open oceans regarding extreme events of temperature, with MHWs being more frequent and longer and extending over larger areas, while the opposite is seen for MCSs. These trends can be explained by changes in both the mean of and variance in sea-surface temperature. In addition, the pace of evolution and dynamics of marine extreme events differ among the subregions. Among the three studied subregions, the English Channel is the region experiencing the strongest increase in summer MHW activity over the last 4 decades. Summer MHWs were very active in the English Channel in 2022 due to long events, in the Bay of Biscay in 2018 due to intense events and in the Bay of Brest in 2017 due to a high occurrence of events. Winter MCSs were the largest in 1987 and 1986 due to long and intense events in the English Channel. Finally, our findings suggest that at an interannual timescale, the positive North Atlantic Oscillation favors the generation of strong summer MHWs in the northeastern Atlantic, while low-pressure conditions over northern Europe and a high off the Iberian Peninsula in winter dominate for MCSs. A preliminary analysis of air–sea heat fluxes suggests that, in this region, reduced cloud coverage is a key parameter for the generation of summer MHWs, while strong winds and increased cloud coverage are important for the generation of winter MCSs.

查看原文本刊更多论文

东北大西洋的沿海和区域性海洋热浪和寒流

摘要政府间气候变化专门委员会(IPCC)的最新报告描述了全球海洋中海洋热浪(MHWs)的数量和强度的增加以及海洋冷期(MCSs)的减少。然而，这些报告的变化在区域和地方的基础上并不统一，沿海地区是否遵循开放海洋的趋势仍然未知。我们分析了东北大西洋和三个次区域(英吉利海峡、布雷斯特湾和比斯开湾)的卫星(1982-2022年)和13个沿海浮标(1990-2022年)收集的海洋表面温度测量数据。活动指标结合了事件数量、强度、持续时间和空间范围，用于评估这些极端事件的震级。每个研究区域的现场和卫星数据集的结果非常一致，尽管卫星数据集低估了mhw和mcs的活动幅度。这支持了该方法对现场和卫星数据的适用性，尽管对这些事件的振幅要谨慎。此外，这项针对欧洲沿海东北大西洋水域的局部研究强调，在沿海和开阔海洋中也出现了类似的极端温度事件变化，强热带风暴更加频繁、持续时间更长、覆盖范围更大，而MCSs则相反。这些趋势可以用海面温度的平均值和方差的变化来解释。此外，各分区域的海洋极端事件的演化速度和动态也存在差异。在研究的三个次区域中，英吉利海峡是过去40年来夏季暖流活动增加最强烈的区域。由于事件长，2022年夏季mhw在英吉利海峡非常活跃，2018年在比斯开湾由于事件强烈，2017年在布雷斯特湾由于事件高发生率。1987年和1986年是冬季mcs最大的年份，这是由于英吉利海峡长时间和强烈的事件造成的。最后，我们的研究结果表明，在年际时间尺度上，北大西洋正涛动有利于在大西洋东北部产生强烈的夏季MHWs，而北欧的低压条件和冬季伊比利亚半岛的高压条件则主导了MCSs的产生。对空气-海热通量的初步分析表明，在该地区，云覆盖减少是夏季强热带气旋产生的关键参数，而强风和云覆盖增加是冬季强热带气旋产生的重要参数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Ocean Science 地学-海洋学

CiteScore

5.90

自引率

6.20%

发文量

审稿时长

6-12 weeks

期刊介绍： Ocean Science (OS) is a not-for-profit international open-access scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of ocean science: experimental, theoretical, and laboratory. The primary objective is to publish a very high-quality scientific journal with free Internet-based access for researchers and other interested people throughout the world. Electronic submission of articles is used to keep publication costs to a minimum. The costs will be covered by a moderate per-page charge paid by the authors. The peer-review process also makes use of the Internet. It includes an 8-week online discussion period with the original submitted manuscript and all comments. If accepted, the final revised paper will be published online. Ocean Science covers the following fields: ocean physics (i.e. ocean structure, circulation, tides, and internal waves); ocean chemistry; biological oceanography; air–sea interactions; ocean models – physical, chemical, biological, and biochemical; coastal and shelf edge processes; paleooceanography.