Potential influence of overpressurized gas on the induced seismicity in the St. Gallen deep geothermal project (Switzerland)

Zbinden, Dominik; Rinaldi, Antonio Pio; Diehl, Tobias; Wiemer, Stefan

doi:10.5194/se-2019-156

Cited by 1 publication

(1 citation statement)

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“…A too low subsurface production flow rate results in economic losses while too high flow rates can lead to fluid leak off and reactivation of faults located far from the injection wells. The latter was probably the case of the St. Gallen geothermal project (Zbinden et al, 2019) and possibly of several other injection induced seismicity cases (Ellsworth, 2013;Goebel & Brodsky, 2018;Grigoli et al, 2017;Kim et al, 2018;Lengliné et al, 2014;Yeck et al, 2016). The poorly estimated flow rates partly arise due to the difficulties in detecting the fracture networks in the underground and partly due to the difficulties of estimating fluid flow through rough fractures with complex surface topographies, submitted to large stresses.…”

Section: Introductionmentioning

confidence: 99%

Hydraulic Transport Through Calcite Bearing Faults With Customized Roughness: Effects of Normal and Shear Loading

2020

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Understanding fluid flow in rough fractures is of high importance to large scale geologic processes and to most anthropogenic geo‐energy activities. Here we conducted fluid transport experiments on Carrara marble fractures with a novel customized surface topography. Transmissivity measurements were conducted under mechanical loading conditions representative of deep geothermal reservoirs (normal stresses from 20 to 70 MPa and shear stresses from 0 to 30 MPa). A numerical procedure simulating normal contact and fluid flow through fractures with complex geometries was validated toward experiments. Using it, we isolated the effects of roughness parameters on fracture fluid flow. Under normal loading, we find that (i) the transmissivity decreases with normal loading and is strongly dependent on fault surface geometry and (ii) the standard deviation of heights (hRMS) and macroscopic wavelength of the surface asperities control fracture transmissivity. Transmissivity evolution is nonmonotonic, with more than 4 orders of magnitude difference for small variations of macroscopic wavelength and hRMS roughness. Reversible elastic shear loading has little effect on transmissivity; it can increase or decrease depending on contact geometry and overall stress state on the fault. Irreversible shear displacement (up to 1 mm offset) slightly decreases transmissivity and its variation with irreversible shear displacements can be predicted numerically and geometrically at low normal stress only. Finally, irreversible changes in surface roughness (plasticity and wear) due to shear displacement result in a permanent decrease of transmissivity when decreasing differential stress. Generally, reduction of a carbonate fault's effective stress increases its transmissivity while inducing small shear displacements does not.

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