GPR-inferred fracture aperture widening in response to a high-pressure tracer injection test at the Äspö Hard Rock Laboratory, Sweden

Details

Ressource 1Download: 2021_Molron_et_al_EngineeringGeology.pdf (6145.49 [Ko])
State: Public
Version: Final published version
License: CC BY-NC-ND 4.0
Serval ID
serval:BIB_2018C810AB5D
Type
Article: article from journal or magazin.
Collection
Publications
Institution
Title
GPR-inferred fracture aperture widening in response to a high-pressure tracer injection test at the Äspö Hard Rock Laboratory, Sweden
Journal
Engineering Geology
Author(s)
Molron Justine, Linde Niklas, Davy Philippe, Baron Ludovic, Darcel Caroline, Selroos Jan-Olof, Le Borgne Tanguy, Doolaeghe Diane
ISSN
0013-7952
Publication state
Published
Issued date
10/2021
Volume
292
Pages
106249
Language
english
Abstract
We assess the performance of the Ground Penetrating Radar (GPR) method in fractured rock formations of very low transmissivity (e.g. T ≈ 10^−9–10^−10 m2/s for sub-mm apertures) and, more specifically, to image fracture widening induced by high-pressure injections. A field-scale experiment was conducted at the Äspö Hard Rock Laboratory (Sweden) in a tunnel situated at 410 m depth. The tracer test was performed within the most transmissive sections of two boreholes separated by 4.2 m. The electrically resistive tracer solution composed of deionized water and Uranine was expected to lead to decreasing GPR reflections with respect to the saline in situ formation water. The injection pressure was 5000 kPa leading to an injection rate of 8.6 mL/min (at steady state) that was maintained during 25 h, which resulted in a total injected volume of 13 L. To evaluate the fracture pathways between the boreholes, we conducted 3-D surface-based GPR surveys before and at the end of the tracer tests, using 160 MHz and 450 MHz antennas. Difference GPR data between the two acquisitions highlight an increasing fracture reflectivity in-between the boreholes at depths corresponding to the injection interval. GPR-based modeling suggests that the observed increasing reflectivity is not due to the tracer solution, but rather to a 50% widening of the fracture. Considering prevailing uncertainties in material properties, a hydromechanical analysis suggests that such a degree of widening is feasible. This research demonstrates that field-scale in situ GPR experiments may provide constraints on fracture widening by high-pressure injection and could help to constrain field-scale elastic parameters in fractured rock.
Keywords
Geotechnical Engineering and Engineering Geology, Geology
Open Access
Yes
Funding(s)
European Commission / H2020 / 722028
Create date
03/08/2021 20:37
Last modification date
04/08/2021 6:08
Usage data