Abstract
Deep geothermal energy (DGE) represents an opportunity for a sustainable and carbon-free energy supply. One of the main concerns of DGE is induced seismicity that may produce damaging earthquakes, challenging its widespread exploitation. It is widely believed that the seismicity risk can be controlled by using doublet systems circulating water to minimize the injection-induced pressure changes. However, cold water reinjection may also give rise to thermal stresses within and beyond the cooled region, whose potential impacts on fault reactivation are less well understood. Here, we investigate by coupled thermo-hydro-mechanical modeling the processes that may lead to fault reactivation in a hot sedimentary aquifer (HSA) in which water is circulated through a doublet. We show that thermal stresses are transmitted much ahead of the cooled region and are likely to destabilize faults located far away from the doublet. Meanwhile, the fault permeability mainly controls the fault reactivation timing, which entails the importance of employing appropriate characterization methods. This investigation is crucial for understanding the mechanisms controlling induced seismicity associated with DGE in a HSA and allows the success of future DGE projects.
Highlights
Deep geothermal energy (DGE) represents an opportunity for a sustainable and carbon-free energy supply
We present the results of coupled thermo-hydro-mechanical (THM) numerical models that simulate a DGE system exploiting with a doublet in a hot sedimentary aquifer (HSA) bounded by two normal faults (Fig. 1, see “Methods” for details of the numerical model)
Cold water reinjection during exploitation of the simulated geothermal reservoir cools down the region around the reinjection well and feeds into heat flow
Summary
Deep geothermal energy (DGE) represents an opportunity for a sustainable and carbon-free energy supply. It is widely believed that the seismicity risk can be controlled by using doublet systems circulating water to minimize the injection-induced pressure changes. The fault permeability mainly controls the fault reactivation timing, which entails the importance of employing appropriate characterization methods This investigation is crucial for understanding the mechanisms controlling induced seismicity associated with DGE in a HSA and allows the success of future DGE projects. The demand for carbon-free energies is rapidly increasing to face global problems like air pollution and climate change, both resulting from the utilization of fossil fuels. This decarbonization is a challenging task that requires the combination of a suite of technologies. The temporal and spatial uncertainties of causuality in recorded seismic events necessitate reconsideration of other triggering mechanisms, among them, thermal effects
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