Toward an AI-enhanced hydro-morphodynamic model for nature-based solutions in coastal erosion mitigation

IF 4.3 2区工程技术 Q1 ENGINEERING, OCEAN Applied Ocean Research Pub Date : 2024-11-17 DOI:10.1016/j.apor.2024.104326

Nour Dammak, Wei Chen, Joanna Staneva

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Abstract

In the application of sustainable Nature-based Solution (NbS) for coastal engineering, a significant challenge lies in determining the effectiveness of these NbS approaches in mitigating coastal erosion. The efficacy of NbS is influenced by various factors, including the specific location, layout, and the scale of implementation. This study integrates artificial intelligence (AI) with hydro-morphodynamic numerical simulations to develop an AI-based emulator focused on predicting Bed Level Changes (BLC) as indicators of erosion and deposition dynamics. Specifically, we explore the influence of seagrass meadows, varying in starting depth (hs) and depth range (hr), on coastal erosion mitigation during storm events.

The framework leverages a hybrid approach combining the SCHISM-WWM hydrodynamic model with XBeach for simulating 180 depth range and starting depth combination (h_r-h_s) scenarios along the Norderney coast in the German Bight. A Convolutional Neural Network (CNN) architecture is employed with dual inputs—roller energy and Eulerian velocity—to predict BLC efficiently. The CNN demonstrates high accuracy in replicating spatial erosion patterns and quantifying erosion volumes, achieving an RMSE of 3.47 cm and an R² of 0.94 during validation.

This innovative integration of AI and NbS not only reduces computational costs associated with traditional numerical modelling but also enhances the feasibility of What-if Scenarios applications for coastal erosion management. The findings underscore the potential of AI-driven approaches to optimize seagrass transplantation layouts and inform sustainable coastal protection strategies effectively. Future advancements aim to further streamline model integration and scalability, thereby advancing NbS applications in enhancing coastal resilience against environmental stressors.

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建立人工智能增强型水文形态动力学模型，为减缓海岸侵蚀提供基于自然的解决方案

在将可持续的 "基于自然的解决方案"（NbS）应用于海岸工程的过程中，面临的一个重大挑战是如何确定这些 NbS 方法在减缓海岸侵蚀方面的有效性。NbS 的效果受到各种因素的影响，包括具体位置、布局和实施规模。本研究将人工智能（AI）与水文形态动力学数值模拟相结合，开发了一个基于人工智能的模拟器，重点预测作为侵蚀和沉积动态指标的床面变化（BLC）。具体而言，我们探索了海草草甸在起始深度（hs）和深度范围（hr）上的变化对风暴事件期间海岸侵蚀减缓的影响。该框架采用了一种混合方法，将 SCHISM-WWM 流体动力模型与 XBeach 相结合，模拟了德国湾 Norderney 海岸沿线的 180 个深度范围和起始深度组合（hr-hs）情景。采用卷积神经网络（CNN）架构，利用双重输入--滚筒能量和欧拉速度--有效预测 BLC。该 CNN 在复制空间侵蚀模式和量化侵蚀量方面表现出很高的准确性，在验证过程中实现了 3.47 厘米的 RMSE 和 0.94 的 R² 。研究结果凸显了人工智能驱动方法在优化海草移植布局和有效告知可持续海岸保护战略方面的潜力。未来的发展目标是进一步简化模型集成和可扩展性，从而推动 NbS 应用于提高沿海地区抵御环境压力的能力。

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来源期刊

Applied Ocean Research 地学-工程：大洋

CiteScore

8.70

自引率

7.00%

发文量

316

审稿时长

59 days

期刊介绍： The aim of Applied Ocean Research is to encourage the submission of papers that advance the state of knowledge in a range of topics relevant to ocean engineering.