Rapid field application of hydraulic tomography for resolving aquifer heterogeneity in unconsolidated sediments

Brauchler, R.; Hu, Rui; Hu, Linwei; Jiménez, S.; Bayer, Peter; Dietrich, Peter; Ptak, Thomas

doi:10.1002/wrcr.20181

Cited by 60 publications

(48 citation statements)

References 42 publications

(53 reference statements)

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“…3D transient HT (THT) involves conducting a series of discrete‐interval pumping tests with discrete‐interval pressure observations at multiple locations, and the data are analyzed through inversion of all tests together. HT has been evolving over the past two decades (Gottlieb and Dietrich ); numerical and laboratory examples have contributed to HT operational improvements including increased effectiveness in observation types, times, and networks (e.g., Cardiff et al ; Sun et al ), and in computational efficiencies (Liu and Kitanidis ; Brauchler et al ; Cardiff et al ; Jiménez et al ; Liu et al , ; Lee and Kitanidis ). Cardiff and Barrash () provided a comprehensive summary of 2D and 3D HT studies.…”

Section: Introductionmentioning

confidence: 99%

Hydraulic Tomography: Continuity and Discontinuity of High‐K and Low‐K Zones

Hochstetler¹,

Barrash

Leven

et al. 2015

Groundwater

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Hydraulic tomography is an emerging field and modeling method that provides a continuous hydraulic conductivity (K) distribution for an investigated region. Characterization approaches that rely on interpolation between one-dimensional (1D) profiles have limited ability to accurately identify high-K channels, juxtapositions of lenses with high K contrast, and breaches in layers or channels between such profiles. However, locating these features is especially important for groundwater flow and transport modeling, and for design and operation of in situ remediation in complex hydrogeologic environments. We use transient hydraulic tomography to estimate 3D K in a volume of 15-m diameter by 20-m saturated thickness in a highly heterogeneous unconfined alluvial (clay to sand-and-gravel) aquifer with a K range of approximately seven orders of magnitude at an active industrial site in Assemini, Sardinia, Italy. A modified Levenberg-Marquardt algorithm was used for geostatistical inversion to deal with the nonlinear nature of the highly heterogeneous system. The imaging results are validated with pumping tests not used in the tomographic inversion. These tests were conducted from three of five clusters of continuous multichannel tubing (CMTs) installed for observation in the tomographic testing. Locations of high-K continuity and discontinuity, juxtaposition of very high-K and very low-K lenses, and low-K "plugs" are evident in regions of the investigated volume where they likely would not have been identified with interpolation from 1D profiles at the positions of the pumping well and five CMT clusters. Quality assessment methods identified a suspect high-K feature between the tested volume and a lateral boundary of the model.

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Section: Introductionmentioning

confidence: 99%

Hydraulic Tomography: Continuity and Discontinuity of High‐K and Low‐K Zones

Hochstetler¹,

Barrash

Leven

et al. 2015

Groundwater

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“…To improve spatial resolution, they applied staggered grids (Vesnaver and Böhm, 2000) during inversion. This inversion methodology was applied to several hydraulic laboratory and field experiments (Brauchler et al, 2007(Brauchler et al, , 2013bHu et al, 2011;Jiménez et al, 2013). Brauchler et al (2013a) also utilized travel times in a tracer experiment on rock samples on the laboratory scale.…”

Section: Introductionmentioning

confidence: 99%

Travel-time-based thermal tracer tomography

Somogyvári

Bayer

Brauchler

2016

Hydrol. Earth Syst. Sci.

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Abstract. Active thermal tracer testing is a technique to get information about the flow and transport properties of an aquifer. In this paper we propose an innovative methodology using active thermal tracers in a tomographic setup to reconstruct cross-well hydraulic conductivity profiles. This is facilitated by assuming that the propagation of the injected thermal tracer is mainly controlled by advection. To reduce the effects of density and viscosity changes and thermal diffusion, early-time diagnostics are used and specific travel times of the tracer breakthrough curves are extracted. These travel times are inverted with an eikonal solver using the staggered grid method to reduce constraints from the predefined grid geometry and to improve the resolution. Finally, non-reliable pixels are removed from the derived hydraulic conductivity tomograms. The method is applied to successfully reconstruct cross-well profiles as well as a 3-D block of a high-resolution fluvio-aeolian aquifer analog data set. Sensitivity analysis reveals a negligible role of the injection temperature, but more attention has to be drawn to other technical parameters such as the injection rate. This is investigated in more detail through model-based testing using diverse hydraulic and thermal conditions in order to delineate the feasible range of applications for the new tomographic approach.

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“…In this context, modern field investigations on aquifers are oriented toward the so-called hydraulic tomography, a flavor of which is based on the concept that performing multiple hydraulic tests in a suite of wells would increase our ability to probe flow conditions and achieve improved control on model parameter identification (e.g., Brauchler et al, 2013;Illman, 2014). As application-oriented examples, experimental observations from hydraulic tomography campaigns based on slug tests and interference testing between wells have been employed in various analytical and numerical models to estimate hydraulic parameters in highly heterogeneous karstic aquifers (Audouin et al, 2008;Riva et al, 2009;Trottier et al, 2014).…”

Section: Introductionmentioning

confidence: 99%