Abstract
The ability to predict the magnitude of an earthquake caused by deep fluid injections is an important factor for assessing the safety of the reservoir storage and the seismic hazard. Here, we propose a new approach to evaluate the seismic energy released during fluid injection by integrating injection parameters, induced aseismic deformation, and the distance of earthquake sources from injection. We use data from ten injection experiments performed at a decameter scale into fault zones in limestone and shale formations. We observe that the seismic energy and the hydraulic energy similarly depend on the injected fluid volume (V), as they both scale as V3/2. They show, however, a large discrepancy, partly related to a large aseismic deformation. Therefore, to accurately predict the released seismic energy, aseismic deformation should be considered in the budget through the residual deformation measured at the injection. Alternatively, the minimal hypocentral distance from injection points and the critical fluid pressure for fault reactivation can be used for a better prediction of the seismic moment in the total compilation of earthquakes observed during these experiments. Complementary to the prediction based only on the injected fluid volume, our approach opens the possibility of using alternative monitoring parameters to improve traffic-light protocols for induced earthquakes and the regulation of operational injection activities.
Highlights
Over the last decades, important increases in the seismicity rates have been observed in relation with anthropogenic activities, especially underground fluid injections and productions[1]
Since the pioneering linear relationship proposed by McGarr[12,13], it is well accepted that the induced seismic moment (Mo) scales with the injected fluid volume (V)
We show that the seismic energy scales as the hydraulic energy with the injected fluid volume as V3/2 when the aseismic deformation is included in the energy budget
Summary
Important increases in the seismicity rates have been observed in relation with anthropogenic activities, especially underground fluid injections and productions[1]. Wastewater injections, associated with shale gas extraction, have induced earthquakes with magnitude up to 5.8 in Oklahoma (USA). The seismogenic index[15] (see method for its definition), together with the injected volume or the pressure rate, has been used to this aim to forecast the evolution on the injection-induced earthquakes in Oklahoma[29,30]. This parameter empirically gathers information on the stress state, the fault network and its frictional properties. We focus on estimating what monitoring data contribute in the released seismicity, while considering the aseismic component of the deformation in the energy budget
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