Temporal filtering and time-lapse inversion of geoelectrical data for long-term monitoring with application to a chlorinated hydrocarbon contaminated site

Nivorlis, Aristeidis; Rossi, Matteo; Dahlin, Torleif

doi:10.1093/gji/ggab422

Cited by 3 publications

(1 citation statement)

References 70 publications

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“…An additional benefit is that it can help evaluate hydraulic conductivity (e.g., Binley et al., 2016; Fiandaca et al., 2018b; Weller et al., 2015). Recent studies show encouraging results for monitoring the injection of ZVI reagents with surface time‐lapse ERT/IP (Flores Orozco et al., 2015, 2019; Nivorlis et al., 2021). Surface ERT/IP imposes a trade‐off between spatial resolution and depth of investigation, due to the attenuation of current injected from the surface.…”

Section: Introductionmentioning

confidence: 99%

Quantifying Reagent Spreading by Cross‐Borehole Electrical Tomography to Assess Performance of Groundwater Remediation

Levy

Thalund-Hansen

Fiandaca

et al. 2022

Water Resources Research

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Industrial application of environmentally hazardous substances have led to contamination of important groundwater aquifers worldwide. Decreasing groundwater quality poses risks to human health, water and food supply, and biodiversity. In Europe, a total of 2.8 million contaminated sites was estimated in 2017 (Pérez & Eugenio, 2018), while in the US, the legal authorities had to manage up to 1.3 million contaminated sites in 2017 (U.S. Environmental Protection Agency, 2017). In Denmark, groundwater is the primary source for drinking water and >36,000 contaminated sites were registered in 2018 (Olsen et al., 2020). Source zone remediation by excavation is a typical, but expensive method that can lead to a significant carbon footprint (Søndergaard et al., 2018). In many cases, the source zone contamination depletes and creates a contamination plume in the groundwater aquifer (Fjordbøge et al., 2017;Murray et al., 2019;Steelman et al., 2020).The development of cost-effective in situ remediation technologies, where contaminant plumes are directly treated in the groundwater, is a high priority (

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Section: Introductionmentioning

confidence: 99%

Quantifying Reagent Spreading by Cross‐Borehole Electrical Tomography to Assess Performance of Groundwater Remediation

Levy

Thalund-Hansen

Fiandaca

et al. 2022

Water Resources Research

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Managing the remediation strategy of contaminated megasites using field-scale calibration of geo-electrical imaging with chemical monitoring

Lévy,

Bording,

Fiandaca

et al. 2024

Science of The Total Environment

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Dielectric Monitoring for understanding Herbicide Bioremediation in Microcosm experiment

Balwant,

Bramhanwade,

Mitkari

et al. 2023

Preprint

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Geophysical tools have emerged as a potential solution to monitor bioremediation of petroleum contaminated soil. Monitoring of herbicide bioremediation so far is lacking. In the present study, we formulated a geophysical approach for monitoring herbicides bioremediation in agriculture soil. Complex dielectric permittivity and conductivity was used to monitored in four microcosm setups i.e., control, herbicide contaminated soil, bioaugmentation and biostimulation. Real and imaginary dielectric permittivity showed different patterns of temporal changes for four microcosms. In the bioagumentated microcosm, the degradation was more prominent and real dielectric permittivity increased twice and achieved peak. Achieved two peaks signify two distinct phenomenon of herbicide degradation and can be further explained through conductivity spectrum and microbial count approach. The major interesting phenomenon observed during the study was shift in peak frequency of imaginary conductivity due to increased biomass during herbicide degradation process. Complex Dielectric permittivity indicated the ability to monitor bioremediation herbicide contaminated soil when it was coupled with complex conductivity method. We expect the insights of the study will be relevant to promote multidisciplinary approach of using geophysical tools for monitoring microbial signatures. The results provide insights how this non-invasive geophysical toll can revolutionize the process of understanding the decontamination process.

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Temporal filtering and time-lapse inversion of geoelectrical data for long-term monitoring with application to a chlorinated hydrocarbon contaminated site

Cited by 3 publications

References 70 publications

Quantifying Reagent Spreading by Cross‐Borehole Electrical Tomography to Assess Performance of Groundwater Remediation

Quantifying Reagent Spreading by Cross‐Borehole Electrical Tomography to Assess Performance of Groundwater Remediation

Managing the remediation strategy of contaminated megasites using field-scale calibration of geo-electrical imaging with chemical monitoring

Dielectric Monitoring for understanding Herbicide Bioremediation in Microcosm experiment

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