A new global database to improve predictions of permeability distribution in crystalline rocks at site scale

Achtziger-Zupančič, Peter; Loew, Simon; Mariethoz, Grégoire

doi:10.1002/2017jb014106

Cited by 74 publications

(82 citation statements)

References 137 publications

(195 reference statements)

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“…Similar observations were made on cataclasites from the Alpine Fault, New Zealand (Carpenter et al, ). While such trends are difficult to generalize, hydraulic and geothermal data and global data compilations have shown nevertheless that a decrease in permeability with depth is a basic hydromechanical property of the brittle crust (Achtziger‐Zupancic et al, ; Manning & Ingebritsen, ).…”

Section: Discussionmentioning

confidence: 99%

Tracking Fluid Flow in Shallow Crustal Fault Zones: 1. Insights From Single‐Hole Permeability Estimates

et al. 2020

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New in situ measurements to constrain the range, distribution, and spatial (meter-scale) variations of permeability in shallow crustal fault zones are reported based on systematic downhole tests at 0.5-km depth in crystalline rock. Single and cross-hole hydraulic packer tests were performed at a new dedicated test facility hosted in the Grimsel Test Site, in the Swiss Alps, following the technical instrumentation and isolation of discrete fault zones accessed by an array of boreholes. Single-hole test results are presented in this paper, while cross-hole experiments are reported in the companion paper. Our results reveal a sharp spatial falloff in permeability, from 10 -13 to 10 -21 m 2 , with off-fault distances of 1-5 m and characterized by a power-law relation with fracture density. Fractures linking subparallel faults were detected as high-permeability discrete spots several meters away from off-fault damage. Due to the narrow (centimeter-wide) thickness of fault cores, the hydraulic tests presented in this study do not characterize the permeability of fault core materials. The transmissivity of single fractures spans six orders of magnitude (10 -12 to 10 -6 m 2 /s) and is systematically higher in damage zones. In situ stresses appear to have a minor effect on natural, present-day fracture transmissivity at the borehole scale. We suggest that the geometrical and topological properties of fracture systems instead tend to control the permeability of the shallow crustal faults studied.Characterizing the structural properties of exhumed fault is key to understand their geometrical complexity at depth, and field studies have described how brittle damage around faults develops both along-strike and off-fault (i.e., off-plane) as fractures in damage zones organize themselves in response to off-fault stresses. Consequently, their spatial arrangement is not random (Kim et al., 2004;Peacock et al., 2017). Previous

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Section: Discussionmentioning

confidence: 99%

Tracking Fluid Flow in Shallow Crustal Fault Zones: 1. Insights From Single‐Hole Permeability Estimates

et al. 2020

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“…However, the thickness of the aquitard layer ( b ′) is smaller than L con in Wang's leaky model. We can determine that K ′ is equal to 1.58×10 ‐7 m/s before the earthquake and equal to 3.15×10 ‐7 m/s after the earthquake when we set b ′ at 500 m. Based on K con = D con × S s , we can infer the value of K con from the barometric response model when we use a common specific storage S s value for the confining layer (10 ‐8 ; Achtziger‐Zupančič et al, ), so the aquitard hydraulic conductivity will be 6.9×10 ‐9 m/s before the earthquake and 1.4 ×10 ‐8 m/s after the earthquake. This vertical hydraulic conductivity is 1–2 orders of magnitude smaller than the value calculated from the leaky model.…”

Section: Discussionmentioning

confidence: 99%

Large Earthquake Reshapes the Groundwater Flow System: Insight From the Water‐Level Response to Earth Tides and Atmospheric Pressure in a Deep Well

Zhang

Shi

Wang

et al. 2019

Water Resources Research

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Quantitative evaluation of earthquake‐induced permeability changes is important for understanding key geological processes, such as advective transport of heat and solute and the generation of elevated fluid pressure. Many studies have independently documented permeability changes in either an aquifer or an aquitard, but the effects of an earthquake on both the aquifer and aquitard of the same aquifer system are still poorly understood. In this study, we use the well water‐level response to earth tides and atmospheric pressure to study the changes in hydraulic properties in an aquifer and an overlying confining layer in Beijing, China, following the 11 March 2011 Tohoku earthquake in Japan. Our results show that both the tidal response amplitude and the phase shift increased and that the phase shift changed from negative to positive after the earthquake. We identified increased permeability in both the aquifer and aquitard by the barometric response function method. The horizontal transmissivity of the aquifer increased by a factor of 6, and the vertical diffusivity of the aquitard doubled.

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“…Permeability, the ability of a porous material to transmit fluids, is fundamental in controlling the rate in which fluids flow in the surface of the Earth, which impacts a wide variety of shallow and deep Earth processes and water resource evaluation (Achtziger‐Zupančič et al, ; Fan, ; Fan et al, ; Gleeson & Ingebritsen, ; Ingebritsen & Manning, ). The lack of regional permeability data in the past has hampered integration of groundwater dynamics and interactions into regional to global land surface and hydrology models (Bierkens, ; Fan, ).…”

Section: Introductionmentioning

confidence: 99%

Compiling and Mapping Global Permeability of the Unconsolidated and Consolidated Earth: GLobal HYdrogeology MaPS 2.0 (GLHYMPS 2.0)

Huscroft

Gleeson

Hartmann

et al. 2018

Geophysical Research Letters

102

100

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The spatial distribution of subsurface parameters such as permeability are increasingly relevant for regional to global climate, land surface, and hydrologic models that are integrating groundwater dynamics and interactions. Despite the large fraction of unconsolidated sediments on Earth's surface with a wide range of permeability values, current global, high‐resolution permeability maps distinguish solely fine‐grained and coarse‐grained unconsolidated sediments. Representative permeability values are derived for a wide variety of unconsolidated sediments and applied to a new global map of unconsolidated sediments to produce the first geologically constrained, two‐layer global map of shallower and deeper permeability. The new mean logarithmic permeability of the Earth's surface is −12.7 ± 1.7 m2 being 1 order of magnitude higher than that derived from previous maps, which is consistent with the dominance of the coarser sediments. The new data set will benefit a variety of scientific applications including the next generation of climate, land surface, and hydrology models at regional to global scales.

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A new global database to improve predictions of permeability distribution in crystalline rocks at site scale

Cited by 74 publications

References 137 publications

Tracking Fluid Flow in Shallow Crustal Fault Zones: 1. Insights From Single‐Hole Permeability Estimates

Tracking Fluid Flow in Shallow Crustal Fault Zones: 1. Insights From Single‐Hole Permeability Estimates

Large Earthquake Reshapes the Groundwater Flow System: Insight From the Water‐Level Response to Earth Tides and Atmospheric Pressure in a Deep Well

Compiling and Mapping Global Permeability of the Unconsolidated and Consolidated Earth: GLobal HYdrogeology MaPS 2.0 (GLHYMPS 2.0)

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