Institute of Environmental Assessment and Water Research, Spanish National Research Council (IDAEA-CSIC), Barcelona, Spain.
Associated Unit: Hydrogeology Group (UPC-CSIC), Barcelona, Spain.
Sci Rep. 2022 Feb 8;12(1):2065. doi: 10.1038/s41598-022-06067-0.
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.
深部地热能(DGE)代表了一种可持续和无碳的能源供应机会。DGE 的主要关注点之一是诱发地震,它可能会产生破坏性的地震,这对其广泛开发构成了挑战。人们普遍认为,可以通过使用循环水的双井系统来控制地震风险,以最小化注入引起的压力变化。然而,冷水回注也可能在冷却区域内外产生热应力,其对断层复活的潜在影响还不太清楚。在这里,我们通过耦合热-水-力学模型研究了在热沉积含水层(HSA)中可能导致断层复活的过程,其中水通过双井循环。我们表明,热应力会在冷却区域之前传播很远,并可能使远离双井的断层失稳。同时,断层渗透率主要控制着断层复活的时间,这需要采用适当的特征描述方法。这项研究对于理解控制与 HSA 中 DGE 相关的诱发地震的机制至关重要,也为未来的 DGE 项目的成功提供了可能。
