Subtle Land Subsidence Elevates Future Storm Surge Risks Along the Gulf Coast of the United States

IF 3.5 2区地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Journal of Geophysical Research: Earth Surface Pub Date : 2024-09-03 DOI:10.1029/2024JF007858

Ke Wang, Jingyi Chen, Eirik Valseth, Gordon Wells, Srinivas Bettadpur, Cathleen E. Jones, Clint Dawson

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Abstract

We developed a robust InSAR processing strategy that can effectively mitigate severe decorrelation noise in a large volume of InSAR data. We mapped the average land subsidence rate (2017–2020) over the 131,572 km² Upper Texas and Louisiana coasts from Sentinel-1 data, with ∼2 mm/yr accuracy based on independent GPS and tide gauge validation at 189 locations. The improved InSAR observations reveal widespread subsidence that was previously undetected in coastal wetlands and rural areas with small communities. Our InSAR surface deformation map is at the spatial scale that overlaps with the scale of hydrodynamic model grids. This allows us to integrate InSAR observations into operational storm surge models to analyze future flooding risks due to relative sea level change. We found that these subtle millimeter-to-centimeter subsidence features can substantially increase hurricane-induced inundation, and passive flood mapping (known as the “bathtub” approach) can lead to inaccurate flood risk predictions.

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微妙的土地沉降加剧了美国墨西哥湾沿岸未来的风暴潮风险

我们开发了一种稳健的 InSAR 处理策略，可有效减轻大量 InSAR 数据中严重的相关性噪声。根据 189 个地点的独立 GPS 和验潮仪验证，我们利用哨兵-1 数据绘制了 131,572 平方公里的上德克萨斯州和路易斯安那州海岸的平均地面沉降率（2017-2020 年），精度达到 2 毫米/年。改进后的 InSAR 观测结果表明，在沿海湿地和拥有小型社区的农村地区，以前没有发现的大面积沉降现象已经出现。我们的 InSAR 表面变形图的空间尺度与水动力模型网格的尺度重叠。这样，我们就可以将 InSAR 观测数据整合到风暴潮运行模型中，分析相对海平面变化导致的未来洪水风险。我们发现，这些微妙的毫米到厘米级的沉降特征会大大增加飓风引起的淹没，而被动洪水测绘（称为 "浴缸 "方法）会导致不准确的洪水风险预测。

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