Quantification of groundwater storage heterogeneity in weathered/fractured basement rock aquifers using electrical resistivity tomography: Sensitivity and uncertainty associated with petrophysical modelling

González, Jesús Alberto Mézquita; Comte, Jean-Christophe; Legchenko, Anatoly; Ofterdinger, Ulrich; Healy, David

doi:10.1016/j.jhydrol.2020.125637

Cited by 35 publications

(5 citation statements)

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“…[25]), and hard rock aquifers [26]. Other studies have also provided additional quantitative information on the aquifer properties, such as storage properties and recharge processes [27,28]. However, due to their complexity and lack of data on petrophysical model input parameters, only a small number of studies have evaluated the relationship between geophysical measures and hydraulic properties in hard rock aquifers [29,30].…”

Section: Introductionmentioning

confidence: 99%

Field surveys in heterogeneous rock masses aimed at hydraulic conductivity assessment

Chicco,

Comina,

Mandrone

et al. 2023

SN Appl. Sci.

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In heterogeneous and fractured rock masses, joints are the most important elements controlling the hydraulic conductivity. Joints parameters are therefore crucial for estimating transport of mass and energy in many technical problems (e.g., slope stability, tunnels, geothermal and oil and gas studies). Hydraulic conductivity conceptual models follow well understood generalizations, but their quantitative estimation is not simple. Both laboratory and field tests have many limitations due to representativeness and scale effects. This study proposes a methodology for a preliminary hydraulic conductivity estimation in fractured and/or heterogeneous rock masses through a combination of in-situ geomechanical and geophysical measurements. Contact and no-contact geomechanical surveys were coupled with electric resistivity topographies in two selected test sites within a Mexican geothermal area in the framework of the Ge-Mex H2020 project. The test sites are representative of two different geological settings: a faulted rock mass with expected high hydraulic conductivity in proximity of the faulted areas and an abandoned marble quarry, with very good mechanical characteristics and negligible degree of fracturing. Moreover, both of them are located in remote areas with limited accessibility, in which rapid, time and cost-effective procedures are welcomed and recommended. The preliminary findings of this study were promising: estimated hydraulic conductivities were compared with independent laboratory measurements performed by other researchers showing a good correspondence and reliability. The proposed methodology demonstrated its reliability in decision making, in the technical support and its economical applicability also in similar difficult logistic situations. Article Highlights A combination of in-situ geomechanical and geophysical measurements was adopted for a preliminary hydraulic conductivity estimation; Obtained field data were compared with independent laboratory estimations to assess the reliability of the proposed approach and compare representativeness and scale effects; Even given the difficult logistic conditions and the limitations of the available comparisons the proposed methodology demonstrated its reliability in decision making.

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Section: Introductionmentioning

confidence: 99%

Field surveys in heterogeneous rock masses aimed at hydraulic conductivity assessment

Chicco,

Comina,

Mandrone

et al. 2023

SN Appl. Sci.

View full text Add to dashboard Cite

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“…1 ). We assume that variations in the subsurface electrical properties, as imaged by surface and airborne geophysical methods, are predominantly driven by variations in lithology, the effective porosity, and fracture density or weathering of the underlying rock [e.g., ( 41 )]. To eliminate the effect of varying lithology, we are focusing our analysis on the dominant lithological unit (Mancos Shale).…”

Section: Introductionmentioning

confidence: 99%

Surface parameters and bedrock properties covary across a mountainous watershed: Insights from machine learning and geophysics

et al. 2022

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Bedrock property quantification is critical for predicting the hydrological response of watersheds to climate disturbances. Estimating bedrock hydraulic properties over watershed scales is inherently difficult, particularly in fracture-dominated regions. Our analysis tests the covariability of above- and belowground features on a watershed scale, by linking borehole geophysical data, near-surface geophysics, and remote sensing data. We use machine learning to quantify the relationships between bedrock geophysical/hydrological properties and geomorphological/vegetation indices and show that machine learning relationships can estimate most of their covariability. Although we can predict the electrical resistivity variation across the watershed, regions of lower variability in the input parameters are shown to provide better estimates, indicating a limitation of commonly applied geomorphological models. Our results emphasize that such an integrated approach can be used to derive detailed bedrock characteristics, allowing for identification of small-scale variations across an entire watershed that may be critical to assess the impact of disturbances on hydrological systems.

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“…The characterization of fractured aquifers remains particularly complicated. In recent years, many efforts have been made to characterize fractures (e.g., Guevara-Mansilla et al, 2020;Molron et al, 2020;Mézquita González et al, 2021), to model them using discrete fracture network (Maillot et al, 2016;Medici et al, 2021) or to include those characteristics in calibration processes (Ringel et al, 2019;Medici et al, 2021). However, the identification of individual fractures can only be made locally using borehole data or high-resolution geophysical methods such as ground penetrating radar (Molron et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…In this context, geophysical methods can bring relevant information to characterize the structure of the aquifer and reveal the presence of fractured zones (e.g., Robert et al, 2011;Binley et al, 2015;Van Hoorde et al, 2017). Given their sensitivity to the porosity and water content, electromagnetic methods are particularly suited for the characterization of fractures inducing a secondary porosity (Schmutz et al, 2011;Mézquita González et al, 2021). Recently, airborne electromagnetic surveys have gained popularity as they can provide dense information at the catchment-scale up to a depth of several hundred meters (e.g., Barfod et al, 2018;Knight et al, 2018;Vilhelmsen et al, 2018;Minsley et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Assessing the Impact of Fractured Zones Imaged by ERT on Groundwater Model Prediction: A Case Study in a Chalk Aquifer in Voort (Belgium)

Riet

Six²,

Walraevens

et al. 2022

Front. Water

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Fractured and karst aquifers are important groundwater reservoirs and are widely used to provide drinking water to the population. Because of the presence of the fractures with varying geometry and properties providing preferential flow paths, fractured aquifers are highly heterogeneous and difficult to characterize and model. In this context, geophysical methods can provide relevant spatially distributed data about the presence of fractures, that can be further integrated in hydrological and groundwater models. In this contribution, we present a case study of a groundwater extraction site in a fractured chalk aquifer in Voort (Belgium), used for the production of drinking water. First, the presence of fractures in the vicinity of the extraction site and their orientation is imaged using electrical resistivity tomography. Based on the available data and the objectives of the study, it is chosen to model only the groundwater component and to simplify the unsaturated zone processes through an average recharge rate. Then, the detected fractures are included in the groundwater model to improve the calibration and the predictive capacity of the model. The results show that a set of parallel fractures crosses the modeled area, whose orientation is in accordance with the tectonic setting. Including these fractures in the model, a more satisfactory calibration was achieved, helping to better understand the hydrogeological behavior of the aquifer. Finally, the acquired knowledge is used to propose new management scenarios for the extraction site minimizing its impact.

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Quantification of groundwater storage heterogeneity in weathered/fractured basement rock aquifers using electrical resistivity tomography: Sensitivity and uncertainty associated with petrophysical modelling

Cited by 35 publications

References 83 publications

Field surveys in heterogeneous rock masses aimed at hydraulic conductivity assessment

Field surveys in heterogeneous rock masses aimed at hydraulic conductivity assessment

Surface parameters and bedrock properties covary across a mountainous watershed: Insights from machine learning and geophysics

Assessing the Impact of Fractured Zones Imaged by ERT on Groundwater Model Prediction: A Case Study in a Chalk Aquifer in Voort (Belgium)

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