Thermal drawdown and late‐stage seismic‐slip fault reactivation in enhanced geothermal reservoirs

Gan, Quan; Elsworth, Derek

doi:10.1002/2014jb011323

Cited by 28 publications

(20 citation statements)

References 27 publications

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“…A hot-fractured-rock project was launched at Cooper Basin, South Australia, in 2002 to exploit the Habanero granite reservoir at a depth of 4000-4500 m. Various stimulation experiments have been conducted which triggered earthquakes with moment magnitude between 1.7 and 3.1 with hypocentral distances between 2.4 and 7.8 km and depth between 3900 and 4500 m [Baisch et al, 2006]. In these cases, thermal drawdown of the rock superpose to the pressure change due to fluid injection causing significant changes in the effective stress regime, which in turn can increase the likelihood of fault reactivation and consequently, induced seismicity [Gan and Elsworth, 2014].…”

Section: Induced Seismicitymentioning

confidence: 99%

“…A reconnaissance study aiming to identify major geological discontinuities is of paramount importance, along with a modeling tool capable of predicting fault/thrust activation resulting from the removal or injection of fluid Gan and Elsworth, 2014;Jha and Juanes, 2014;Teatini et al, 2014]. With the aid of an ad hoc model we can estimate the sliding of the fault/thrust, and hence predict the seismic moment.…”

Section: 1002/2014wr016841mentioning

confidence: 99%

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Geomechanics of subsurface water withdrawal and injection

Gambolati

Teatini

2015

Water Resources Research

127

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Land subsidence and uplift, ground ruptures, and induced seismicity are the principal geomechanic effects of groundwater withdrawal and injection. The major environmental consequence of groundwater pumping is anthropogenic land subsidence. The first observation concerning land settlement linked to subsurface processes was made in 1926 by the American geologists Pratt and Johnson, who wrote that ''the cause of subsidence is to be found in the extensive extraction of fluid from beneath the affected area.'' Since then, impressive progress has been made in terms of: (a) recognizing the basic hydrologic and geomechanic principles underlying the occurrence; (b) measuring aquifer compaction and ground displacements, both vertical and horizontal; (c) modeling and predicting the past and future event; and (d) mitigating environmental impact through aquifer recharge and/or surface water injection. The first milestone in the theory of pumped aquifer consolidation was reached in 1923 by Terzaghi, who introduced the principle of ''effective intergranular stress.'' In the early 1970s, the emerging computer technology facilitated development of the first mathematical model of the subsidence of Venice, made by Gambolati and Freeze. Since then, the comprehension, measuring, and simulation of the occurrence have improved dramatically. More challenging today are the issues of ground ruptures and induced/ triggered seismicity, which call for a shift from the classical continuum approach to discontinuous mechanics. Although well known for decades, anthropogenic land subsidence is still threatening large urban centers and deltaic areas worldwide, such as Bangkok, Jakarta, and Mexico City, at rates in the order of 10 cm/yr.

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Section: Induced Seismicitymentioning

confidence: 99%

Section: 1002/2014wr016841mentioning

confidence: 99%

Geomechanics of subsurface water withdrawal and injection

Gambolati

Teatini

2015

Water Resources Research

127

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“…However, there is no satisfactory numerical model that fully explains the influence of fluid injections on seismic slip at this volcano. We address this gap by building on recent studies that modeled microseismicity in geothermal reservoirs (Gan & Elsworth, 2014a, 2014b; Gan & Lei, 2020) and explained the high‐magnitude seismicity induced, for example, at Geysers geothermal field (Kwiatek et al., 2015).…”

Section: Introductionmentioning

confidence: 99%

Thermo‐Hydro‐Mechanical Model and Caprock Deformation Explain the Onset of an Ongoing Seismo‐Volcanic Unrest

et al. 2021

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Modeling seismicity at volcanoes remains challenging as the processes that control seismic energy release due to fluid transport, heat flow, and rock deformation are firmly coupled in complex geological media. Here, we couple fluid‐flow and mechanical (deformation) simulators (TOUGHREACT–FLAC3D) to reproduce fluid‐induced seismicity at Campi Flegrei caldera (southern Italy) in isothermal (HM) and nonisothermal (THM) conditions. The unique ability of the Campi Flegrei caprock to withstand stress induced by hot‐water injections is included in the model parametrization. After pore pressure accumulation is guided by a combination of thermal and hydromechanical interactions, contrasting compressive and extensional forces act on the basal and top parts of the caprock, respectively. Then, pressure perturbation and caprock deformation induce fractures that allow hot fluids uprising to pressurize the overlying fault, driving it toward failure and triggering seismicity. Under similar mechanical boundary conditions, the induced thermal effects prompt seismic slip earlier but with higher seismic magnitudes when (1) thermal equilibrium is preserved and (2) the thermal contrast is enhanced due to increased fluid injection temperatures. The results indicate that numerical models of volcano seismicity must consider the influence of rock‐sealing formations to obtain more robust, accurate, and realistic seismic predictions at volcanoes. The proposed models satisfactorily reproduce the magnitude–depth distribution of the swarm (October 5, 2019), preceding the two strongest earthquakes recorded in 35 years at the caldera (3.1 and 3.3—on December 6, 2019, and April 26, 2020, respectively) using hot‐water injection from depth.

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“…In this study, we focus exclusively on the prolonged fluid re-injection and assume a successful stimulation of the wells’ surroundings already took place. Although the connection between cooling and reservoir stability is known and numerical studies applied to traditional geothermal systems have highlighted the influence of thermal gradients 45 , fault and rock permeability 46 , stress regime 30 , competition between thermal and hydraulic processes 47 and tensile fracturing effects on permeability 48 , the issue has never been addressed in ESGS systems. Specifically, cooling in ESGS could take on a whole new dimension, as the potential temperature drop and associated thermal stress variation can be very high.…”

Section: Introductionmentioning

confidence: 99%

The risks of long-term re-injection in supercritical geothermal systems

et al. 2019

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Supercritical geothermal systems are appealing sources of sustainable and carbon-free energy located in volcanic areas. Recent successes in drilling and exploration have opened new possibilities and spiked interest in this technology. Experimental and numerical studies have also confirmed the feasibility of creating fluid conducting fractures in sedimentary and crystalline rocks at high temperature, paving the road towards Enhanced Supercritical Geothermal Systems. Despite their attractiveness, several important questions regarding safe exploitation remain open. We dedicate this manuscript to the first thermo-hydro-mechanical numerical study of a doublet geothermal system in supercritical conditions. Here we show that thermally-induced stress and strain effects dominate the geomechanical response of supercritical systems compared to pore pressure-related instabilities, and greatly enhance seismicity during cold water re-injection. This finding has important consequences in the design of Supercritical Geothermal Systems.

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Thermal drawdown and late‐stage seismic‐slip fault reactivation in enhanced geothermal reservoirs

Cited by 28 publications

References 27 publications

Geomechanics of subsurface water withdrawal and injection

Geomechanics of subsurface water withdrawal and injection

Thermo‐Hydro‐Mechanical Model and Caprock Deformation Explain the Onset of an Ongoing Seismo‐Volcanic Unrest

The risks of long-term re-injection in supercritical geothermal systems

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