Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods

Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods

<p>Ground-penetrating radar (GPR) and seismic imaging have proven to be important tools for the characterization of rock volumes. Both methods provide information about the physical rock mass properties and geological structures away from boreholes or tunnel walls. Here, we present the results...

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Main Authors: J. Doetsch, H. Krietsch, C. Schmelzbach, M. Jalali, V. Gischig, L. Villiger, F. Amann, H. Maurer
Format: Article
Language:English
Published: Copernicus Publications 2020-08-01
Series:Solid Earth
Online Access:https://se.copernicus.org/articles/11/1441/2020/se-11-1441-2020.pdf
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spelling doaj-2482ee643770406d991373cc034964a62020-11-25T02:58:22ZengCopernicus PublicationsSolid Earth1869-95101869-95292020-08-01111441145510.5194/se-11-1441-2020Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methodsJ. Doetsch0H. Krietsch1H. Krietsch2C. Schmelzbach3M. Jalali4V. Gischig5L. Villiger6F. Amann7H. Maurer8Department of Earth Sciences, ETH Zurich, Zurich, SwitzerlandDepartment of Engineering Geology and Hydrogeology, RWTH Aachen, Aachen, GermanyiLF Consulting Engineers, Zurich, SwitzerlandDepartment of Earth Sciences, ETH Zurich, Zurich, SwitzerlandDepartment of Engineering Geology and Hydrogeology, RWTH Aachen, Aachen, GermanyCSD Engineers, Bern, SwitzerlandSwiss Seismological Service, ETH Zurich, Zurich, SwitzerlandDepartment of Engineering Geology and Hydrogeology, RWTH Aachen, Aachen, GermanyDepartment of Earth Sciences, ETH Zurich, Zurich, Switzerland<p>Ground-penetrating radar (GPR) and seismic imaging have proven to be important tools for the characterization of rock volumes. Both methods provide information about the physical rock mass properties and geological structures away from boreholes or tunnel walls. Here, we present the results from a geophysical characterization campaign that was conducted as part of a decametre-scale hydraulic stimulation experiment in the crystalline rock volume of the Grimsel Test Site (central Switzerland). For this characterization experiment, we used tunnel-based GPR reflection imaging as well as seismic travel-time tomography to investigate the volumes between several tunnels and boreholes. The interpretation of the GPR data with respect to geological structures is based on the unmigrated and migrated images. For the tomographic analysis of the seismic first-arrival travel-time data, we inverted for an anisotropic velocity model described by the Thomsen parameters <span class="inline-formula"><i>v</i><sub>0</sub></span>, <span class="inline-formula"><i>ϵ</i></span> and <span class="inline-formula"><i>δ</i></span> to account for the rock mass foliation. Subsequently, the GPR and seismic images were interpreted in combination with the geological model of the test volume and the known in situ stress states. We found that the ductile shear zones are clearly imaged by GPR and show an increase in seismic anisotropy due to a stronger foliation, while they are not visible in the <span class="inline-formula"><i>p</i></span>-wave (<span class="inline-formula"><i>v</i><sub>0</sub></span>) velocity model. Regions of decreased seismic <span class="inline-formula"><i>p</i></span>-wave velocity, however, correlate with regions of high fracture density. For geophysical characterization of potential deep geothermal reservoirs, our results imply that wireline-compatible borehole GPR should be considered for shear zone characterization, and that seismic anisotropy and velocity information are desirable to acquire in order to gain information about ductile shear zones and fracture density, respectively.</p>https://se.copernicus.org/articles/11/1441/2020/se-11-1441-2020.pdf
collection DOAJ
language English
format Article
sources DOAJ
author J. Doetsch
H. Krietsch
H. Krietsch
C. Schmelzbach
M. Jalali
V. Gischig
L. Villiger
F. Amann
H. Maurer
spellingShingle J. Doetsch
H. Krietsch
H. Krietsch
C. Schmelzbach
M. Jalali
V. Gischig
L. Villiger
F. Amann
H. Maurer
Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods
Solid Earth
author_facet J. Doetsch
H. Krietsch
H. Krietsch
C. Schmelzbach
M. Jalali
V. Gischig
L. Villiger
F. Amann
H. Maurer
author_sort J. Doetsch
title Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods
title_short Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods
title_full Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods
title_fullStr Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods
title_full_unstemmed Characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods
title_sort characterizing a decametre-scale granitic reservoir using ground-penetrating radar and seismic methods
publisher Copernicus Publications
series Solid Earth
issn 1869-9510
1869-9529
publishDate 2020-08-01
description <p>Ground-penetrating radar (GPR) and seismic imaging have proven to be important tools for the characterization of rock volumes. Both methods provide information about the physical rock mass properties and geological structures away from boreholes or tunnel walls. Here, we present the results from a geophysical characterization campaign that was conducted as part of a decametre-scale hydraulic stimulation experiment in the crystalline rock volume of the Grimsel Test Site (central Switzerland). For this characterization experiment, we used tunnel-based GPR reflection imaging as well as seismic travel-time tomography to investigate the volumes between several tunnels and boreholes. The interpretation of the GPR data with respect to geological structures is based on the unmigrated and migrated images. For the tomographic analysis of the seismic first-arrival travel-time data, we inverted for an anisotropic velocity model described by the Thomsen parameters <span class="inline-formula"><i>v</i><sub>0</sub></span>, <span class="inline-formula"><i>ϵ</i></span> and <span class="inline-formula"><i>δ</i></span> to account for the rock mass foliation. Subsequently, the GPR and seismic images were interpreted in combination with the geological model of the test volume and the known in situ stress states. We found that the ductile shear zones are clearly imaged by GPR and show an increase in seismic anisotropy due to a stronger foliation, while they are not visible in the <span class="inline-formula"><i>p</i></span>-wave (<span class="inline-formula"><i>v</i><sub>0</sub></span>) velocity model. Regions of decreased seismic <span class="inline-formula"><i>p</i></span>-wave velocity, however, correlate with regions of high fracture density. For geophysical characterization of potential deep geothermal reservoirs, our results imply that wireline-compatible borehole GPR should be considered for shear zone characterization, and that seismic anisotropy and velocity information are desirable to acquire in order to gain information about ductile shear zones and fracture density, respectively.</p>
url https://se.copernicus.org/articles/11/1441/2020/se-11-1441-2020.pdf
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