Evolution of structure and permeability of normal faults with clay smear: Insights from water‐saturated sandbox models and numerical simulations

Kettermann, Michael; Urai, János L.; Vrolijk, Peter

doi:10.1002/2016jb013341

Cited by 12 publications

(13 citation statements)

References 66 publications

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“…The main goal of this work is providing new insight on the impact of stratigraphically-consistent fault material arrangements with clay smears on fault permeability. In § 3 in the main text we validate PREDICT with cm-scale experiments by Kettermann et al (2017), and we also compare our results to those from Sperrevik et al (2002)'s permeability predictor and other laboratory and field measurements in similar geology. A multi-scale, 3-component validation of PREDICT's output requires quantifying the mismatch between the permeability distributions and measurements of the macroscale fault permeability in m-to km-scale faults.…”

Section: Nomenclaturementioning

confidence: 71%

“…• Along-strike smear segment number (s s ): This parameter defines the segmentation of smears in the strikeparallel direction, and is based on the hole mappings in excavated fault surfaces by Kettermann et al (2016Kettermann et al ( , 2017; Noorsalehi-Garakani et al (2013). We counted the number of holes along strike-parallel, horizontal lines of length equal to f D to define the maximum and minimum number of holes (N h ).…”

Section: S121 Marginal Distributionsmentioning

confidence: 99%

“…greater effective stress, leading to higher SSFc (C ¸iftc ¸i et al, 2013;Clausen and Gabrielsen, 2002;Giger et al, 2013;Sperrevik et al, 2000). The endpoints can be further modified to account for hybrid failure in very shallow faults (e.g., Kettermann et al, 2017), such that discontinuous smears may appear at any value of f D . Finally, the endpoints are adjusted to account for the scale factor, which leads to smaller faults displaying larger SSFc (Faerseth, 2006).…”

Section: S121 Marginal Distributionsmentioning

confidence: 99%

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Supplemental Material: Fault permeability from stochastic modeling of clay smears

Saló-Salgado¹,

Juanes²,

al.³

2022

Preprint

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Section: Nomenclaturementioning

confidence: 71%

Section: S121 Marginal Distributionsmentioning

confidence: 99%

Section: S121 Marginal Distributionsmentioning

confidence: 99%

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Supplemental Material: Fault permeability from stochastic modeling of clay smears

Saló-Salgado¹,

Juanes²,

al.³

2022

Preprint

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“…For instance, fault-related processes, such as clay smear (Vrolijk et al 2016), can drastically influence permeability of a fault, e.g., by acting as a barrier to fluid flow. The existence of clay smear alone, however, is not a defining indicator on the permeability of the fault, as potential breaching of the clay layer coincides with increased flow across the fault (Kettermann et al 2017). Furthermore, experimental data showed that the influence of clay smear on permeability changes with fault activity, i.e., rock deformation (Takahashi 2003).…”

Section: Discussionmentioning

confidence: 99%

Analyzing the influence of correlation length in permeability on convective systems in heterogeneous aquifers using entropy production

2019

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Hydrothermal convection in porous geothermal reservoir systems can be seen as a double-edged sword. On the one hand, regions of upflow in convective systems can increase the geothermal energy potential of the reservoir; on the other hand, convection introduces uncertainty, because it can be difficult to locate these regions of upflow. Several predictive criteria, such as the Rayleigh number, exist to estimate whether convection might occur under certain conditions. As such, it is of interest which factors influence locations of upwelling regions and how these factors can be determined. We use the thermodynamic measure entropy production to describe the influence of spatially heterogeneous permeability on a hydrothermal convection pattern in a 2D model of a hot sedimentary aquifer system in the Perth Basin, Western Australia. To this end, we set up a Monte Carlo study with multiple ensembles. Each ensemble contains several hundred realizations of spatially heterogeneous permeability. The ensembles only differ in the horizontal spatial continuity (i.e., correlation length) of permeability. The entropy production of the simulated ensembles shows that the convection patterns in our models drastically change with the introduction and increase of a finite, lateral correlation length in permeability. An initial decrease of the average entropy production number with increasing lateral correlation length shows that fewer ensemble members show convection. When neglecting the purely conductive ensembles in our analysis, no significant change in the number of convection cells is seen for lateral correlation lengths larger than 2000 m. The result suggests that the strength of convective heat transfer is not sensitive to changes in lateral correlation length beyond a specific factor. It does, however, change strongly compared to simulations with a homogeneous permeability field. As such, while the uncertainty in spatial continuity of permeability may not strongly influence the convective heat transfer, our findings show that it is important to consider spatial heterogeneity and continuity of permeability when simulating convective heat transfer in an aquifer.

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“…in faulted deposits, and by sedimentary structures as shown by Lapperre et al (1996) who studied heterogeneity using hydraulic conductivity measurements on 271 undisturbed core samples taken in horizontal, vertical and 'structure' direction. Based on water-saturated model experiments (Schmatz et al, 2010) and multiple experiments using a water-saturated sandbox to simulate clay smear, Kettermann et al (2017) concluded that flow patterns under these circumstances are complex and three-dimensional. Vertical temperature profiles in nests of piezometers in unconsolidated sedimentary aquifers in the German opencast lignite mining area also indicate fault zone heterogeneity.…”

Section: Fault Zone Permeability and Heterogeneitymentioning

confidence: 99%

An overview of fault zone permeabilities and groundwater level steps in the Roer Valley Rift System

Lapperre

Kasse

Bense

et al. 2019

Netherlands Journal of Geosciences

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Faults in the Roer Valley Rift System (RVRS) act as barriers to horizontal groundwater flow. This causes steep cross-fault groundwater level steps (hydraulic head differences). An overview of the size and distribution of fault-related groundwater level steps and associated fault zone permeabilities is thus far lacking. Such an overview would provide useful insights for nature restoration projects in areas with shallow groundwater levels (wijstgronden) on the foot wall of fault zones. In this review study, data on fault zone permeabilities and cross-fault hydraulic head differences were compiled from 39 sources of information, consisting of literature (starting from 1948), internal reports (e.g. from research institutes and drinking water companies), groundwater models, a geological database and new fieldwork. The data are unevenly distributed across the RVRS. Three-quarters of the data sources are related to the Peel Boundary Fault zone (PBFZ). This bias is probably caused by the visibility of fault scarps and fault-adjacent wet areas for the PBFZ, with the characteristic iron-rich groundwater seepage. Most data demonstrate a cross-fault phreatic groundwater level step of 1.0 to 2.5 m. Data for the Feldbiss Fault zone (FFZ) show phreatic cross-fault hydraulic head differences of 1.0 to 2.0 m. In situ measured hydraulic conductivity data (K) are scarce. Values vary over three orders of magnitude, from 0.013 to 22.1 m d−1, are non-directional and do not take into account heterogeneity caused by fault zones. The hydraulic conductivity (and hydraulic resistance) values used in three different groundwater models are obtained by calibration using field measurements. They also cover a large range, from 0.001 to 32 m d−1 and from 5 to 100,000 days. Heterogeneity is also not taken into account in these models. The overview only revealed locations with a clear cross-fault groundwater level step, and at many locations the faults are visible on aerial photographs as cropmarks or as soil moisture contrasts at the surface. Therefore, it seems likely that all faults have a reduced permeability, which determines the size of the groundwater level steps. In addition, our results show that cross-fault hydraulic head gradients also correlate with topographic, fault-induced offsets, for both the Peel Boundary and the Feldbiss fault zone.

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Evolution of structure and permeability of normal faults with clay smear: Insights from water‐saturated sandbox models and numerical simulations

Cited by 12 publications

References 66 publications

Supplemental Material: Fault permeability from stochastic modeling of clay smears

Supplemental Material: Fault permeability from stochastic modeling of clay smears

Analyzing the influence of correlation length in permeability on convective systems in heterogeneous aquifers using entropy production

An overview of fault zone permeabilities and groundwater level steps in the Roer Valley Rift System

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