Application of an iterative source localization strategy at a chlorinated solvent site

IF 3.1 Q2 GEOSCIENCES, MULTIDISCIPLINARY Journal of Hydrology X Pub Date : 2021-12-01 DOI:10.1016/j.hydroa.2021.100111
E. Essouayed, T. Ferré, G. Cohen, N. Guiserix, O. Atteia
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引用次数: 3

Abstract

This study presents an inverse modeling strategy for organic contaminant source localization. The approach infers the hydraulic conductivity field, the dispersivity, and the source zone location. Beginning with initial observed data of contaminant concentration and hydraulic head, the method follows an iterative strategy of adding new observations and revising the source location estimate. Non-linear optimization using the Gauss-Levenberg-Marquardt Algorithm (PEST++) is tested at a real contaminated site. Then a limited number of drilling locations are added, with their positions guided by the Data Worth analysis capabilities of PYEMU. The first phase of PEST++, with PYEMU guidance, followed by addition of monitoring wells provided an initial source location and identified four additional drilling locations. The second phase confirmed the source location, but the estimated hydraulic conductivity field and the Darcy flux were too far from the measured values. The mismatch led to a revised conceptual site model that included two distinct zones, each with a plume emanating from a separate source. A third inverse modelling phase was conducted with the revised site conceptual model. Finally, the source location was compared to results from a Geoprobe@ MiHPT campaign and historical records, confirming both source locations. By merging measurement and modeling in a coupled, iterative framework, two contaminant sources were located through only two drilling campaigns while also reforming the conceptual model of the site.

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迭代源定位策略在氯化溶剂位置的应用
本研究提出了一种有机污染源定位的逆建模策略。该方法推导出水导率场、色散和震源区位置。该方法从污染物浓度和水头的初始观测数据开始,遵循添加新观测值和修改源位置估计的迭代策略。在实际污染现场进行了非线性优化测试,采用了gaus - levenberg - marquardt算法。然后添加有限数量的钻井位置,这些位置由PYEMU的数据价值分析功能指导。在PYEMU的指导下,PEST++的第一阶段,随后增加了监测井,提供了初始源位置,并确定了四个额外的钻井位置。第二阶段确定了源位置,但估算的水力导电性场和达西通量与实测值相差太远。这种不匹配导致了一个修订的概念站点模型,该模型包括两个不同的区域,每个区域都有来自不同来源的羽流。第三个逆向建模阶段使用修订后的站点概念模型进行。最后,将源位置与Geoprobe@ MiHPT活动的结果和历史记录进行比较,确认两个源位置。通过在一个耦合的、迭代的框架中合并测量和建模,仅通过两次钻探活动就确定了两个污染源,同时也改变了场地的概念模型。
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来源期刊
Journal of Hydrology X
Journal of Hydrology X Environmental Science-Water Science and Technology
CiteScore
7.00
自引率
2.50%
发文量
20
审稿时长
25 weeks
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