A data-driven approach for simplifying the estimation of time for contaminant plumes to reach their maximum extent

IF 3.5 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Journal of contaminant hydrology Pub Date : 2024-03-22 DOI:10.1016/j.jconhyd.2024.104336

A. Köhler , P.K. Yadav , R. Liedl , J.B. Shil , T. Grischek , P. Dietrich

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引用次数: 0

Abstract

Globally there exist a very large number of contaminated or possibly contaminated sites where a basic preliminary assessment has not been completed. This is largely, among others, due to limited simple methods/models available for estimating key site quantities such as the maximum plume length, further denoted as $L_{\max}$ and the corresponding time $T = T_{Lmax}$ , at which the plume reaches its maximum extent $L = L_{\max}$ . An approach to easily obtain an estimate of $T_{Lmax}$ in particular is presented in this work. Limited availability of high-quality field data, particularly of $T_{Lmax}$ , necessitates the use of synthetic data, which constrains the overall model development works. Taking BIOSCREEN-AT (transient 3D model) as a base model, this work proposes second-order polynomial models, with only two parameters, for estimating $L_{\max}$ and $T_{Lmax}$ . This reformulation of the well established solution significantly reduces data requirement and workload for initial site assessment purposes. A global sensitivity analysis (Morris, 1991), using a large number of random synthetic data, identifies the first-order decay rate constants in the plume $(λ_{EFF})$ and at the source $(γ)$ as dominantly most influential for $T_{Lmax}$ . For $L_{\max}$ , the first-order decay rate constant $λ_{EFF}$ and groundwater velocity $v$ are the two important parameters. The sensitivity analysis also identifies that these parameters non-linearly impact $T_{Lmax}$ or $L_{\max}$ . With this information, the proposed polynomial models (each for $L_{\max}$ and $T_{Lmax}$ ) were trained to obtain model coefficients, using a large amount of synthetic data. For verification, the developed models were tested using four datasets comprising over 100 sample sets against the results obtained from BIOSCREEN-AT and the developed BIOSCREEN-AT-based steady-state model. Additionally, the developed models were evaluated against two well documented field sites. The proposed models largely simplify estimation, particularly, of $T_{Lmax}$ , for which only very limited field or literature information is available.

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简化污染物羽流达到最大范围时间估算的数据驱动方法

全球有大量受污染或可能受污染的场地尚未完成基本的初步评估。除其他原因外，这在很大程度上是由于用于估算关键场地数量的简单方法/模型有限，例如最大羽流长度（进一步表示为 Lmax）以及羽流达到最大范围 L=Lmax 时的相应时间 T=TLmax。本研究提出了一种可以轻松获得最大羽流长度估计值的方法。由于高质量的实地数据，特别是 TLmax 数据有限，因此必须使用合成数据，这限制了整个模型的开发工作。本研究以 BIOSCREEN-AT（瞬态三维模型）为基础模型，提出了只有两个参数的二阶多项式模型，用于估算 Lmax 和 TLmax。对这一成熟解决方案的重新制定，大大减少了数据需求和初步现场评估的工作量。使用大量随机合成数据进行的全局敏感性分析（Morris，1991 年）发现，羽流 λEFF 和源 γ 中的一阶衰减速率常数对 TLmax 的影响最大。对于 Lmax，一阶衰减速率常数 λEFF 和地下水速度 v 是两个重要参数。敏感性分析还发现，这些参数对 TLmax 或 Lmax 有非线性影响。根据这些信息，利用大量的合成数据对所提出的多项式模型（Lmax 和 TLmax 模型）进行了训练，以获得模型系数。为了进行验证，使用了四个数据集（包括 100 多个样本集），对照 BIOSCREEN-AT 和基于 BIOSCREEN-AT 开发的稳态模型得出的结果，对所开发的模型进行了测试。此外，还根据两个有据可查的实地地点对所开发的模型进行了评估。所提出的模型在很大程度上简化了估算，尤其是 TLmax 的估算，因为只有非常有限的现场或文献信息可用于估算。

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来源期刊

Journal of contaminant hydrology 环境科学-地球科学综合

CiteScore

6.80

自引率

2.80%

发文量

129

审稿时长

68 days

期刊介绍： The Journal of Contaminant Hydrology is an international journal publishing scientific articles pertaining to the contamination of subsurface water resources. Emphasis is placed on investigations of the physical, chemical, and biological processes influencing the behavior and fate of organic and inorganic contaminants in the unsaturated (vadose) and saturated (groundwater) zones, as well as at groundwater-surface water interfaces. The ecological impacts of contaminants transported both from and to aquifers are of interest. Articles on contamination of surface water only, without a link to groundwater, are out of the scope. Broad latitude is allowed in identifying contaminants of interest, and include legacy and emerging pollutants, nutrients, nanoparticles, pathogenic microorganisms (e.g., bacteria, viruses, protozoa), microplastics, and various constituents associated with energy production (e.g., methane, carbon dioxide, hydrogen sulfide). The journal''s scope embraces a wide range of topics including: experimental investigations of contaminant sorption, diffusion, transformation, volatilization and transport in the surface and subsurface; characterization of soil and aquifer properties only as they influence contaminant behavior; development and testing of mathematical models of contaminant behaviour; innovative techniques for restoration of contaminated sites; development of new tools or techniques for monitoring the extent of soil and groundwater contamination; transformation of contaminants in the hyporheic zone; effects of contaminants traversing the hyporheic zone on surface water and groundwater ecosystems; subsurface carbon sequestration and/or turnover; and migration of fluids associated with energy production into groundwater.