Coupled hydrogeophysical inversion through ensemble smoother with multiple data assimilation and convolutional neural network for contaminant plume reconstruction

IF 3.9 3区 环境科学与生态学 Q1 ENGINEERING, CIVIL Stochastic Environmental Research and Risk Assessment Pub Date : 2024-08-25 DOI:10.1007/s00477-024-02800-5
Camilla Fagandini, Valeria Todaro, Cláudia Escada, Leonardo Azevedo, J. Jaime Gómez-Hernández, Andrea Zanini
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Abstract

In the field of groundwater, accurate delineation of contaminant plumes is critical for designing effective remediation strategies. Typically, this identification poses a challenge as it involves solving an inverse problem with limited concentration data available. To improve the understanding of contaminant behavior within aquifers, hydrogeophysics emerges as a powerful tool by enabling the combination of non-invasive geophysical techniques (i.e., electrical resistivity tomography—ERT) and hydrological variables. This paper investigates the potential of the Ensemble Smoother with Multiple Data Assimilation method to address the inverse problem at hand by simultaneously assimilating observed ERT data and scattered concentration values from monitoring wells. A novelty aspect is the integration of a Convolutional Neural Network (CNN) to replace and expedite the expensive geophysical forward model. The proposed approach is applied to a synthetic case study, simulating a tracer test in an unconfined aquifer. Five scenarios are compared, allowing to explore the effects of combining multiple data sources and their abundance. The outcomes highlight the efficacy of the proposed approach in estimating the spatial distribution of a concentration plume. Notably, the scenario integrating apparent resistivity with concentration values emerges as the most promising, as long as there are enough concentration data. This underlines the importance of adopting a comprehensive approach to tracer plume mapping by leveraging different types of information. Additionally, a comparison was conducted between the inverse procedure solved using the full geophysical forward model and the CNN model, showcasing comparable performance in terms of results, but with a significant acceleration in computational time.

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通过集合平滑器与多重数据同化和卷积神经网络进行耦合水文地质物理反演,以重建污染物羽流
在地下水领域,准确划定污染物羽流对于设计有效的修复策略至关重要。通常情况下,这种识别是一项挑战,因为它涉及到在浓度数据有限的情况下解决反问题。为了更好地了解含水层内污染物的行为,水文地球物理技术成为一种强大的工具,它可以将非侵入性地球物理技术(即电阻率层析成像技术-ERT)与水文变量相结合。本文通过同时同化观测到的电阻率层析成像数据和来自监测井的零散浓度值,研究了多重数据同化集合平滑法在解决当前逆问题方面的潜力。其新颖之处在于整合了卷积神经网络(CNN),以取代并加快昂贵的地球物理前向模型。所提出的方法被应用于一个合成案例研究,模拟在一个非封闭含水层中进行示踪试验。对五种情况进行了比较,以探索结合多种数据源及其丰度的效果。结果凸显了所提出的方法在估算浓度羽流空间分布方面的功效。值得注意的是,只要有足够的浓度数据,视电阻率与浓度值相结合的方案最有前途。这强调了利用不同类型的信息,采用综合方法绘制示踪羽流图的重要性。此外,还对使用完整地球物理前向模型和 CNN 模型求解的反演程序进行了比较,结果表明两者性能相当,但计算时间大大缩短。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.10
自引率
9.50%
发文量
189
审稿时长
3.8 months
期刊介绍: Stochastic Environmental Research and Risk Assessment (SERRA) will publish research papers, reviews and technical notes on stochastic and probabilistic approaches to environmental sciences and engineering, including interactions of earth and atmospheric environments with people and ecosystems. The basic idea is to bring together research papers on stochastic modelling in various fields of environmental sciences and to provide an interdisciplinary forum for the exchange of ideas, for communicating on issues that cut across disciplinary barriers, and for the dissemination of stochastic techniques used in different fields to the community of interested researchers. Original contributions will be considered dealing with modelling (theoretical and computational), measurements and instrumentation in one or more of the following topical areas: - Spatiotemporal analysis and mapping of natural processes. - Enviroinformatics. - Environmental risk assessment, reliability analysis and decision making. - Surface and subsurface hydrology and hydraulics. - Multiphase porous media domains and contaminant transport modelling. - Hazardous waste site characterization. - Stochastic turbulence and random hydrodynamic fields. - Chaotic and fractal systems. - Random waves and seafloor morphology. - Stochastic atmospheric and climate processes. - Air pollution and quality assessment research. - Modern geostatistics. - Mechanisms of pollutant formation, emission, exposure and absorption. - Physical, chemical and biological analysis of human exposure from single and multiple media and routes; control and protection. - Bioinformatics. - Probabilistic methods in ecology and population biology. - Epidemiological investigations. - Models using stochastic differential equations stochastic or partial differential equations. - Hazardous waste site characterization.
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