Drying of Taganrog Bay during wind-driven setdowns from satellite and ADCIRC model data

IF 2.6 3区地球科学 Q1 MARINE & FRESHWATER BIOLOGY Estuarine Coastal and Shelf Science Pub Date : 2024-08-19 DOI:10.1016/j.ecss.2024.108910

A.A. Aleskerova , N.V. Vasilenko , V.V. Fomin , S.V. Stanichny , G.G. Matishov , A.A. Kubryakov

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Abstract

Intense wind-driven setdowns can cause extensive drying of the shallow Taganrog Bay in the Azov Sea, significantly impacting the marine infrastructure and ecosystem. Satellite measurements of MSI Sentinel-2 and OLI Landsat 8 during 2015–2021 were used to identify 28 intense cases of such processes. Using a simple difference method based on near-infrared measurements, we calculated the area of a drying zone (S) and investigated its relation with storm intensity and duration. Our findings indicate that S in the estuarine part of the bay can exceed 300 km². Setdowns most often occurred in the autumn during intense and persistent easterly winds with wind speed exceeding 8 m/s. The largest areas of drying zone (S > 100 km²) were observed during continuous winds lasting more than 10 days. The correlation between the integral action of wind stress and S was 0.74, and for prolonged events (more than 5 days) it was 0.92.

Further, satellite data was used to validate the results of ADCIRC numerical modelling. Based on the modeling data, we investigated the influence of wind speed on the area of bottom drying in order to obtain a simple parameterization of this process. At the initial moment of setdown, the sea level decreases as t^1/2 and linearly depends on the square root of the integral wind stress, while the drying zone increases as t^1/4. The relation between sea level and wind speed was universal for different wind amplitude until an equilibrium state is reached. Interestingly, during most intense winds (>20 m/s), the drying zone decreases, which is related to the drying out of the banks located at the entrance of the Taganrog Bay limiting water outflow from the bay.

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从卫星和 ADCIRC 模型数据看塔甘罗格湾风力落潮期间的干燥情况

强烈的风力落潮会导致亚速海塔甘罗格湾浅海大面积干涸，对海洋基础设施和生态系统造成严重影响。利用 2015-2021 年期间 MSI Sentinel-2 和 OLI Landsat 8 的卫星测量结果，确定了 28 个此类过程的强烈案例。利用基于近红外测量的简单差分法，我们计算了干燥区（S）的面积，并研究了其与风暴强度和持续时间的关系。我们的研究结果表明，海湾河口部分的 S 可超过 300 平方公里。落潮最常发生在风速超过 8 米/秒的秋季强烈持续东风中。在持续风速超过 10 天的情况下，可以观察到最大面积的干燥区（S > 100 平方公里）。风应力的积分作用与 S 之间的相关性为 0.74，在持续时间较长（超过 5 天）的情况下，相关性为 0.92。根据建模数据，我们研究了风速对底部干燥面积的影响，以便对这一过程进行简单的参数化。在着陆的初始时刻，海平面随着 t1/2 的减小而减小，并与积分风应力的平方根成线性关系，而干燥区则随着 t1/4 的增大而增大。在达到平衡状态之前，海平面与风速之间的关系在不同的风幅下是普遍的。有趣的是，在风速最大时（20 米/秒），干燥区减小，这与位于塔甘罗格湾入口处的堤岸干涸有关，因为堤岸干涸限制了海水从海湾流出。

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来源期刊

Estuarine Coastal and Shelf Science 地学-海洋学

CiteScore

5.60

自引率

7.10%

发文量

374

审稿时长

9 months

期刊介绍： Estuarine, Coastal and Shelf Science is an international multidisciplinary journal devoted to the analysis of saline water phenomena ranging from the outer edge of the continental shelf to the upper limits of the tidal zone. The journal provides a unique forum, unifying the multidisciplinary approaches to the study of the oceanography of estuaries, coastal zones, and continental shelf seas. It features original research papers, review papers and short communications treating such disciplines as zoology, botany, geology, sedimentology, physical oceanography.