Modelling and inferring fracture curvature from borehole GPR data: A case study from the Bedretto Laboratory, Switzerland

Escallon, Daniel; Shakas, Alexis; Maurer, Hansruedi

doi:10.1002/nsg.12286

Cited by 3 publications

(1 citation statement)

References 64 publications

(82 reference statements)

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“…This fault zone model has been used for forward GPR simulation, following the modeling approach of Shakas and Linde (2015) for comparison to the GPR measurements. To account for the slight curvature resulting from the interpolation, the novel meshing approach has been employed, which is introduced in Escallon et al (2023). The results from remote sensing allowed us to identify three main sets of lineaments, showing different orientation, spatial distribution, lateral persistence and relative frequency at the scales of observation (Fig.…”

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confidence: 99%

Selection and Characterisation of the Target Fault for Fluid-Induced Activation and Earthquake Rupture Experiments

Achtziger-Zupančič,

Ceccato,

Zappone

et al. 2024

Preprint

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Abstract. Performing stimulation experiments at approximately 1 km depth in the Bedretto Underground Laboratory for Geosciences and Geoenergies necessitates identifying and characterizing the target fault zone for on-fault monitoring of induced fault-slip and seismicity, a current challenge in understanding seismogenic processes. We discuss the multidisciplinary approach for selecting the target fault zone for the experiments planned within the Fault Activation and Earthquake Ruptures (FEAR) project, aiming to induce fault-slip and seismicity up to a magnitude 1.0 earthquake while enhancing monitoring and control of fluid-injection experiments. Structural geological mapping, remote sensing, exploration drilling and borehole logging, ground-penetration radar, and laboratory investigations were employed to identify and characterize the target fault – a ductile-brittle shear zone several meters wide with intensely fractured volume persisting over 100 m. Its orientation in the in-situ stress field favors reactivation in normal to strike-slip regimes. Laboratory tests showed slight velocity strengthening of the fault gouge. The fault's architecture, typical for crystalline environments, poses challenges for fluid flow, necessitating detailed hydraulic and stress characterization before each of the FEAR experiments. This multidisciplinary approach was crucial for managing rock volume heterogeneity and understand implications for the dense monitoring network. Successfully identifying the fault sets the stage for seismic activation experiments commencing in spring 2024.

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confidence: 99%

Selection and Characterisation of the Target Fault for Fluid-Induced Activation and Earthquake Rupture Experiments

Achtziger-Zupančič,

Ceccato,

Zappone

et al. 2024

Preprint

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Hydromechanical characterization of a fractured crystalline rock volume during multi-stage hydraulic stimulations at the BedrettoLab

Bröker,

Ma,

Gholizadeh Doonechaly

et al. 2024

Geothermics

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Selection and characterization of the target fault for fluid-induced activation and earthquake rupture experiments

Achtziger-Zupančič,

Ceccato,

Zappone

et al. 2024

Solid Earth

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Abstract. Performing stimulation experiments at approximately 1 km depth in the Bedretto Underground Laboratory for Geosciences and Geoenergies necessitates identifying and characterizing the target fault zone for on-fault monitoring of induced fault slip and seismicity, which presents a challenge when attempting to understand seismogenic processes. We discuss the multidisciplinary approach for selecting the target fault zone for experiments planned within the Fault Activation and Earthquake Ruptures (FEAR) project, for which the aim is to induce the fault slip and seismicity for an earthquake magnitude of up to 1.0 while enhancing the monitoring and control of fluid-injection experiments. Structural geological mapping, remote sensing, exploration drilling and borehole logging, ground-penetration radar, and laboratory investigations were employed to identify and characterize the target fault – a ductile–brittle shear zone several meters wide with an intensely fractured volume spanning over 100 m. Its orientation in the in situ stress field favors reactivation in normal to strike-slip regimes. Laboratory tests showed slight velocity strengthening of the fault gouge. The fault's architecture, typical for crystalline environments, poses challenges for fluid flow, necessitating detailed hydraulic and stress characterization before each of the FEAR experiments. This multidisciplinary approach was crucial for managing rock volume heterogeneity and understanding implications for the dense monitoring network. Successfully identifying the fault sets the stage for seismic activation experiments commencing in spring 2024.

show abstract

Modelling and inferring fracture curvature from borehole GPR data: A case study from the Bedretto Laboratory, Switzerland

Cited by 3 publications

References 64 publications

Selection and Characterisation of the Target Fault for Fluid-Induced Activation and Earthquake Rupture Experiments

Selection and Characterisation of the Target Fault for Fluid-Induced Activation and Earthquake Rupture Experiments

Hydromechanical characterization of a fractured crystalline rock volume during multi-stage hydraulic stimulations at the BedrettoLab

Selection and characterization of the target fault for fluid-induced activation and earthquake rupture experiments

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