Impact of petrophysical uncertainty on Bayesian hydrogeophysical inversion and model selection

Brunetti, Carlotta; Linde, Niklas

doi:10.1016/j.advwatres.2017.11.028

Cited by 28 publications

(36 citation statements)

References 60 publications

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“…But according to Ikard et al (2012), this salinity effect is rather modest (less than 1 order of magnitude) and can be removed by measuring the electrical conductivity of the pore water. Furthermore, one can consider this petrophysical uncertainty in the Bayesian framework by jointly estimating both the distribution of the unknown parameters (e.g., K eff ) and the distribution of petrophysical uncertainty (e.g., Brunetti & Linde, 2018). However, additional petrophysical uncertainty in the ERT and SP inversion will reduce the accuracy of the inversion, and collection of additional data (e.g., a larger amount of ERT and SP measurements) will be necessary.…”

Section: Discussionmentioning

confidence: 99%

Improved Characterization of DNAPL Source Zones via Sequential Hydrogeophysical Inversion of Hydraulic‐Head, Self‐Potential and Partitioning Tracer Data

Kang

Kokkinaki

Kitanidis

et al. 2020

Water Resources Research

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High‐resolution characterization of hydraulic properties and dense nonaqueous phase liquid (DNAPL) contaminant source is crucial to develop efficient remediation strategies. However, DNAPL characterization suffers from a limited number of borehole data in the field, resulting in a low‐resolution estimation. Moreover, high‐resolution DNAPL characterization requires a large number of unknowns to be estimated, presenting a computational bottleneck. In this paper, a low‐cost geophysical approach, the self‐potential method, is used as additional information for hydraulic properties characterization. Joint inversion of hydraulic head and self‐potential measurements is proposed to improve hydraulic conductivity estimation, which is then used to characterize the DNAPL saturation distribution by inverting partitioning tracer measurements. The computational barrier is overcome by (a) solving the inversion by the principal component geostatistical approach, in which the covariance matrix is replaced by a low‐rank approximation, thus reducing the number of forward model runs; (b) using temporal moments of concentrations instead of individual concentration data points for faster forward simulations. To assess the ability of the proposed approach, numerical experiments are conducted in a 3‐D aquifer with 104 unknown hydraulic conductivities and DNAPL saturations. Results show that with realistic DNAPL sources and a limited number of hydraulic heads, the traditional hydraulic/partitioning tracer tomography roughly reconstructs subsurface heterogeneity but fails to resolve the DNAPL distribution. By adding self‐potential data, the error is reduced by 24% in hydraulic conductivity estimation and 68% in DNAPL saturation characterization. The proposed sequential inversion framework utilizes the complementary information from multi‐source hydrogeophysical data sets, and can provide high‐resolution characterizations for realistic DNAPL sources.

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Section: Discussionmentioning

confidence: 99%

Improved Characterization of DNAPL Source Zones via Sequential Hydrogeophysical Inversion of Hydraulic‐Head, Self‐Potential and Partitioning Tracer Data

Kang

Kokkinaki

Kitanidis

et al. 2020

Water Resources Research

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“…An additional, and often overlooked, source of uncertainty in the interpretation of resistivity images is the petrophysical prediction uncertainty, whereby the equations (e.g., Equations (1)–(4)) are inherently uncertain, heterogeneous and characterized by limited predictive power (Brunetti & Linde, 2018). The most common approach remains to use calibrations of the petrophysical relationships (e.g., m and n in Equation (2)) to turn changes in imaged conductivity into changes into a hydrologic state variable.…”

Section: Future Prospects and Challengesmentioning

confidence: 99%

Advancing hydrological process understanding from long‐term resistivity monitoring systems

Slater

Binley

2021

WIREs Water

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Monitoring subsurface flow and transport processes over a wide range of spatiotemporal scales remains one of the greatest challenges in hydrology. Electrical geophysical techniques have been implemented to noninvasively investigate a broad range of subsurface hydrological processes. Recent advances in instrumentation and interpretational tools highlight the emerging opportunities to adopt long‐term resistivity monitoring (LTRM) to improve understanding of flow and transport processes operating over monthly to decadal timescales that are not adequately captured in short‐term monitoring data sets and are temporally aliased in data sets constructed from occasional reoccupation of a study site. The emergence of LTRM as a robust tool in hydrology represents a paradigm shift in geophysical data acquisition and analysis, with resistivity monitoring now evolving into a hydrological decision support technology. We describe the theoretical basis for adopting LTRM for noninvasive monitoring of hydrological state variables over multiple spatial scales and with higher temporal resolution than achieved from periodic reoccupation of a field site. Instrumentation developments facilitating autonomous data acquisition at off the grid field sites are discussed, along with advances in data processing that enhance the hydrological information content inherent in LTRM data sets. Case studies from a diverse range of hydrology subdisciplines highlight the largely untapped potential for LTRM to provide information beyond the reach of established hydrology tools. Future opportunities and challenges relating to the more widespread adoption of LTRM, including addressing inherent uncertainty in resistivity interpretation, upscaling, computational, and modeling needs are critically discussed. This article is categorized under: Science of Water (WCAA)

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“…After data collection, the analysis of resistivity data may also benefit from the use of appropriate appraisal tools (Oldenburg and Li, 1999;Caterina et al, 2013). Additionally, hydrogeophysical SWI studies would be improved by performing uncertainty analysis (Linde et al, 2017), including the evaluation of uncertainty associated to the petrophysical model in the transfer of information between the hydrogeological and geophysical models (Brunetti and Linde, 2018). The results presented in this work suggest that, even for acceptable values of sensitivity, hydrogeological information derived from geophysics must be used with caution in the calibration of groundwater models, especially in heterogeneous aquifers.…”

Section: )mentioning

confidence: 99%

Relative importance of conceptual and computational errors when delineating saltwater intrusion from resistivity inverse models in heterogeneous coastal aquifers

González-Quirós

Comte

2020

Advances in Water Resources

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Highlights:-Inverted resistivity data are commonly used to delineate saltwater intrusion (SWI).-Errors associated to inversion and petrophysical transformation are assessed.-A coupled modelling approach was applied to four synthetic heterogeneous aquifers.-Inversion and salinity recovery errors are equivalent when neglecting heterogeneity.-Spatial quantification of the errors is key for geophysics-aided SWI management.

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Impact of petrophysical uncertainty on Bayesian hydrogeophysical inversion and model selection

Cited by 28 publications

References 60 publications

Improved Characterization of DNAPL Source Zones via Sequential Hydrogeophysical Inversion of Hydraulic‐Head, Self‐Potential and Partitioning Tracer Data

Improved Characterization of DNAPL Source Zones via Sequential Hydrogeophysical Inversion of Hydraulic‐Head, Self‐Potential and Partitioning Tracer Data

Advancing hydrological process understanding from long‐term resistivity monitoring systems

Relative importance of conceptual and computational errors when delineating saltwater intrusion from resistivity inverse models in heterogeneous coastal aquifers

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