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欧洲大西洋沿岸基于卫星的沙质海岸线趋势及年际变化

Satellite-derived sandy shoreline trends and interannual variability along the Atlantic coast of Europe.

作者信息

Castelle Bruno, Kras Etiënne, Masselink Gerd, Scott Tim, Konstantinou Aikaterini, Luijendijk Arjen

机构信息

Univ. Bordeaux, CNRS, Bordeaux INP, EPOC UMR 5805, 33600, Pessac, France.

Deltares, Boussinesqweg, 2629 HV, Delft, The Netherlands.

出版信息

Sci Rep. 2024 Jun 6;14(1):13002. doi: 10.1038/s41598-024-63849-4.

DOI:10.1038/s41598-024-63849-4
PMID:38844510
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11637074/
Abstract

Monitoring sandy shoreline evolution from years to decades is critical to understand the past and predict the future of our coasts. Optical satellite imagery can now infer such datasets globally, but sometimes with large uncertainties, poor spatial resolution, and thus debatable outcomes. Here we validate and analyse satellite-derived-shoreline positions (1984-2021) along the Atlantic coast of Europe using a moving-averaged approach based on coastline characteristics, indicating conservative uncertainties of long-term trends around 0.4 m/year and a potential bias towards accretion. We show that west-facing open coasts are more prone to long-term erosion, whereas relatively closed coasts favor accretion, although most of computed trends fall within the range of uncertainty. Interannual shoreline variability is influenced by regionally dominant atmospheric climate indices. Quasi-straight open coastlines typically show the strongest and more alongshore-uniform links, while embayed coastlines, especially those not exposed to the dominant wave climate, show weaker and more variable correlation with the indices. Our results provide a spatial continuum between previous local-scale studies, while emphasizing the necessity to further reduce satellite-derived shoreline trend uncertainties. They also call for applications based on a relevant averaging approach and the inclusion of coastal setting parameters to unravel the forcing-response spectrum of sandy shorelines globally.

摘要

监测沙质海岸线从数年到数十年的演变对于了解海岸的过去和预测其未来至关重要。光学卫星图像现在可以在全球范围内推断此类数据集,但有时存在很大的不确定性、空间分辨率较差,因此结果存在争议。在这里,我们使用基于海岸线特征的移动平均方法,对欧洲大西洋沿岸的卫星衍生海岸线位置(1984 - 2021年)进行验证和分析,结果表明长期趋势的保守不确定性约为0.4米/年,并且存在向淤积的潜在偏差。我们表明,朝西的开阔海岸更容易受到长期侵蚀,而相对封闭的海岸则有利于淤积,尽管大多数计算趋势都在不确定性范围内。年际海岸线变化受区域主导的大气气候指数影响。准直的开阔海岸线通常显示出最强且沿岸最均匀的联系,而海湾海岸线,尤其是那些未暴露于主导波浪气候的海岸线,与指数的相关性较弱且变化更大。我们的结果在先前的局部尺度研究之间提供了一个空间连续体,同时强调了进一步降低卫星衍生海岸线趋势不确定性的必要性。它们还呼吁基于相关平均方法的应用,并纳入海岸环境参数,以揭示全球沙质海岸线的强迫 - 响应谱。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b2f7/11637074/eb859c0b809a/41598_2024_63849_Fig10_HTML.jpg
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