Abstract
For more than seven decades, the impounding of artificial water reservoirs has been known to trigger earthquakes. Accordingly, reservoir-induced seismicity (RIS) has been studied in terms of its identification and mechanisms. In this paper, we report three laboratory experiments to investigate the effects of water impoundment and pore-pressure diffusion on the reactivation of faults in high tectonic stress areas. Results showed that when the horizontal stress is larger than the vertical stress, according to the Mohr–Coulomb criterion, pore-pressure diffusion might be the main factor inducing seismicity instead of the undrained stress compression. The diffusion and oscillation of pore pressure are the controlling factors in triggering the activation of faults and releasing the elastic energy. The Mohr–Coulomb criterion is consistent in describing the critical damage pore pressure of the pre-existing faults; however, it fails to judge whether a fault is in a stable or unstable state after the pore pressure increases. The hydraulic energy from the injection pressure and volume of water is strongly related to the moment magnitude of the induced seismicity owing to pore-pressure diffusion. Moreover, the fault can be transformed from an unstable state into a stable state after continuous seismic events. The enhancement of fault permeability due to the seismic events can promote the fluid flow through fractures and influence the seepage field around the reservoir.
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References
Bao X, Eaton DW (2016) Fault activation by hydraulic fracturing in western Canada. Science 354(6318):1406–1409
Bell ML, Nur A (1978) Strength changes due to reservoir-induced pore pressure and stresses and application to Lake Oroville. J Geophys Res 83:4469–4483
Brace WF, Walsh JB, Frangos WT (1968) Permeability of granite under high pressure. J Geophys Res 73(6):2225–2236
Carder DS (1945) Seismic investigations in the Boulder Dam area, 1940–1944, and the influence of reservoir loading on local earthquake activity. B Seismol Soc Am 35(4):175–192
Chadha RK, Kuempel HJ, Shekar M (2008) Reservoir Triggered Seismicity (RTS) and well water level response in the Koyna-Warna region, India. Tectonophysics 456:94–102
Chen L, Talwani P (2001) Mechnism of initial seismicity following impoundment of the Monticello Reservoir, South Carolina. B Seismol Soc Am 91(6):1582–1594
Cheng H, Zhang H, Shi Y (2015) High-resolution numerical analysis of the triggering mechanism of M L5.7 Aswan Reservoir Earthquake through fully coupled poroelastic finite Element Modeling. Pure Apply Geophys 173(5):1593–1605
Deng K, Zhou S, Wang R, Robinson R, Zhao C, Cheng W (2010) Evidence that the 2008 Mw 7.9 Wenchuan Earthquake could not have been induced by the Zipingpu Reservoir. B Seismol Soc Am 100(5B):2805–2814
Durá-Gómez I, Talwani P (2010) Reservoir-induced seismicity associated with the Itoiz reservoir, Spain: a case study. Geophys J Int 1:343–356
Fang Y, Elsworth D, Wang C, Jia Y (2018) Mineralogical controls on frictional strength, stability, and shear permeability evolution of fractures. J Geophys Res Solid Earth 123(5):3549–3563
Fine RA, Millero FJ (1973) Compressibility of distilled water and seawater. J Chem Phys 59(10):5529–5536
Goodfellow SD, Nasseri MHB, Maxwell SC, Young RP (2015) Hydraulic fracture energy budget: insights from the laboratory. Geophys Res Lett 42(9):3179–3187
Guglielmi Y, Cappa F, Avouac JP, Henry P, Elsworth D (2015) Seismicity triggered by fluid injection-induced aseismic slip. Science 348(6240):1224–1246
Gupta HK (2002) A review of recent studies of triggered earthquakes by artificial water reservoirs with special emphasis on earthquakes in Koyna, India. Earth-Sci Rev 58(3):279–310
Haggag HM, Bhattacharya PM, Kamal S, Kayal JR (2009) Seismicity and 3D velocity structure in the Aswan Reservoir Lake area, Egypt. Tectonophysics 476:450–459
Hariri ME, Abercrombie RE, Rowe CA, Nascimento AF (2010) The role of fluids in triggering earthquakes: observations from reservoir induced seismicity in Brazil. Geophys J Int 181(3):1566–1574
He GH, Wang EZ, Liu XL (2016) Modified governing equation and numerical simulation of seepage flow in a single fracture with three-dimensional roughness. Arab J Geosci 9:81
Hofmann H, Zimmermann G, Zang A, Min KB (2018) Cyclic soft stimulation (CSS): a new fluid injection protocol and traffic light system to mitigate seismic risks of hydraulic stimulation treatments. Geotherm Energy 6(1):27
Hofmann H, Zimmermann G, Farkas M, Huenges E, Zang A, Leonhardt M, Kwiatek G, Martinez-Garzon P, Bohnhoff M, Min KB, Fokker P, Westaway R, Bethmann F, Meier P, Yoon KS, Choi JW, Lee TJ, Kim KY (2019) First field application of cyclic soft stimulation at the Pohang Enhanced Geothermal System site in Korea. Geophys J Int 217(2):926–949
Huang J, Liu XL, Zhao J, Wang EZ, Wang SJ (2020) Propagation of stress waves through fully saturated rock joint under undrained conditions and dynamic response characteristics of filling liquid. Rock Mech Rock Eng 53:3637–3655. https://doi.org/10.1007/s00603-020-02126-y
Ide S, Beroza GC (2001) Does apparent stress vary with earthquake size? Geophys Res Lett 28(17):3349–3352
Ishibashi T, Watanabe N, Asanuma H, Tsuchiya N (2016) Linking microearthquakes to fracture permeability change: the role of surface roughness. Geophys Res Lett 43(14):7486–7493
Ishibashi T, Elsworth D, Fang Y, Riviere J, Madara B, Asanuma H, Watanabe N, Marone C (2018) Friction-stability-permeability evolution of a fracture in granite. Water Resour Res 54(12):9901–9918
Jiang HK, Song J, Wu Q, Li J, Qu JH (2012) Quantitative investigation of fluid triggering on seismicity in the Three Gorges Reservoir area based on ETAS model, Chinese. Diqiu Wuli Xuebao. 55(7):2341–2352 (in Chinese)
Johann L, Shapiro SA, Dinske C (2018) The surge of earthquakes in Central Oklahoma has features of reservoir-induced seismicity. Sci Rep 8(1):1–14
Kanamori H, Brodsky EE (2004) The physics of earthquakes. Rep Prog Phys 67(8):1429–1496
Korson L, Drost-Hansen W, Millero FJ (1969) Viscosity of water at various temperature. J Phys Chem 73(1):34–39
Li F, An QM, Wang HZ, Zhao SG (2004) Analysis and research on in-situ stress measurement of hydraulic fracturing of Xiluodu Hydropower Station on Jinsha River. Earthq Res China 20(1):95–100
Liu S, Xu L, Talwani P (2011a) Reservoir-induced seismicity in the Danjiangkou Reservoir: a quantitative analysis. Geophys J Int 185(1):514–528
Liu XL, Wang SJ, Wang EZ (2011b) A study on the uplift mechanism of Tongjiezi dam using a coupled hydro-mechanical model. Eng Geol 117(1):134–150
Liu XL, Wang SJ, Wang SY, Wang EZ (2015) Fluid-driven fractures in granular materials. Bull Eng Geol Environ 74(2):621–636
Liu H-H, Chen H, An C (2018a) A criterion for evaluating the effect of shale-matrix dual-continuum flow on gas production. Geomech Geophys Geo-Energy Geo-Resour 5:87–102. https://doi.org/10.1007/s40948-018-0100-z
Liu XL, Han GF, Wang EZ, Wang SJ, Nawnit K (2018b) Multiscale hierarchical analysis of rock mass and prediction of its mechanical and hydraulic properties. J Rock Mech Geotech Eng 10:694–702
Liu XL, Wang F, Huang J, Wang SJ, Zhang ZZ, Nawnit K (2019) Grout diffusion in silty fine sand stratum with high groundwater level for tunnel construction. Tunn Undergr Space Technol 93:103051. https://doi.org/10.1016/j.tust.2019.103051
Lv QF, Wang EZ, Liu XL, Wang SJ (2014) Determining the intrinsic permeability of tight porous media based on bivelocity hydrodynetics. Microfluid Nanofluid 16(5):841–848
Maxwell SC (2011) What does microseismic tell us about hydraulic fracture deformation, CSEG Recorder, 36
Maxwell SC (2013) Unintentional seismicity induced by hydraulic fracturing, CSEG Recorder, 38
Maxwell SC, J Schemeta, E Campbell, and D Quirk (2008) Microseismic deformation rate monitoring. In: Paper presented at SPE Annual Technical Conference and Exhibition, SPE–116596-MS, Denver, Colo., 21–24 Sept
McGarr A, Simpson D (1997) A broad look at induced and triggered seismicity
Ngo DT, Pellet FL, Bruel D (2019) Modeling of fault slip during hydraulic stimulation in a naturally fractured medium. Geomech Geophys Geo-Energy Geo-Resour 5:237–251. https://doi.org/10.1007/s40948-019-00108-1
Passelègue FX, Brantut N, Mitchell TM (2018) Fault reactivation by fluid injection: controls from stress state and injection rate. Geophys Res Lett 45(23):12837–12846
Rabe C, Perdomo PRR, Roux P-F, Silva CG, Gamboa LAP (2019) Coupled fluid flow and geomechanics: a case study in Faja del Orinoco. Geomech Geophys Geo-Energy Geo-Resour 6(1):58
Rahman MK, Hossain MM, Rahman SS (2002) A shear-dilation-based model for evaluation of hydraulically stimulated naturally fractured reservoirs. Int J Numer Anal Met 26(5):469–497
Reyners M (2010) Reservoir-induced seismicity at Lake Pukaki, New Zealand. Geophys J Int 93(1):127–135
Stork AL, Verdon JP, Kendall JM (2015) The microseismic response at the In Salah Carbon Capture and Storage (CCS) site. Int J Greenh Gas Con 32:159–171
Sun H, Liu XL, Zhu JB (2019) Correlational fractal characterization of stress and acoustic emission during coal and rock failure under multilevel dynamic loadings. Int J Rock Mech Min Sci 117:1–10
Talwani P (1997) On the nature of reservoir-induced seismicity. Pure Apply. Geophys. 150:473–492
Tang H, Wasowski J, Juang CH (2019) Geohazards in the three Gorges Reservoir Area, China—Lessons learned from decades of research. Eng Geol 261:105267
Walsh FR, Zoback MD (2015) Oklahoma’s recent earthquakes and saltwater disposal. Sci Adv 1:e1500195
Wangen M (2018) A 3D model of hydraulic fracturing and microseismicity in anisotropic stress fields. Geomech Geophys Geo-Energy Geo-Resour 5:17–35. https://doi.org/10.1007/s40948-018-0096-4
White JA, Foxall W (2014) A phased approach to induced seismicity risk management. Energy Procedia 63:4841–4849
Xie HP, Zhu JB, Zhou T, Zhang K, Zhou C (2020) Conceptualization and preliminary study of engineering disturbed rock dynamics. Geomech Geophys Geo-Energy Geo-Resour 6:34
Xue Q, Feng XT, Liu L, Chen YJ, Liu XL (2013) Evaluation of pavement straw composite fiber on SMA pavement performances. Constr Build Mater 41:834–843
Ying WL, Benson PM, Young RP (2009) Laboratory simulation of fluid-driven seismic sequences in shallow crustal conditions. Geophys Res Lett 36(20):390–406
Yu Y, Wang EZ, Zhong JW, Liu XL, Li PH, Shi M, Zhang ZG (2014) Stability analysis of abutment slopes based on long-term monitoring and numerical simulation. Eng Geol 183:159–169
Zhang L, Li J, Sun X, Liao W, Zhao Y, Wei G, He C (2018) A possible mechanism of reservoir-induced earthquakes in the Three Gorges Reservoir, Central China. B Seismol Soc Am 108:3016–3028
Zhang L, Lei X, Liao W, Li J, Yao Y (2019) Statistical parameters of seismicity induced by the impoundment of the Three Gorges Reservoir, Central China. Tectonophysics 751:13–22
Zhao J (1996) Construction and utilization of rock caverns in Singapore: part A The Bukit Timah granite bedrock resource. Tunn Undergr Sp Technol 11(1):65–72
Zhou L, Zhao C, Chen Z, Zheng S (2011) Three-dimensional V P and V P /V S structure in the Longtan reservoir area by local earthquake tomography. Pure Apply Geophys 169:123–139
Zhu JB, Liao ZY, Tang CA (2016) Numerical SHPB tests of rocks under combined static and dynamic loading conditions with application to dynamic behavior of rocks under in situ stresses. Rock Mech Rock Eng 49(10):3935–3946
Zhuang L, Kim KY, Jung SG, Diaz M, Min KB, Zang A, Stephansson O, Zimmermann G, Yoon JS, Hofmann H (2019) Cyclic hydraulic fracturing of Pocheon granite cores and its impact on breakdown pressure, acoustic emission amplitudes and injectivity. Int J Rock Mech Min 122:104065
Zoback MD, Byerlee JD (1975) The effect of microcrack dilatancy on the permeability of westerly granite. J Geophys Res 80(5):752–755
Zoback MD, Hickman S, Zoback MD (1982) In situ study of the physical mechanisms controlling induced seismicity at Monticello Reservoir, South Carolina. J Geophys Res Solid Earth 87:6959–6974
Funding
This work was supported by the National Key R&D Program of China (Grant No. 2018YFC1504801) and the National Natural Science Foundation of China (Grant No. 41941019, 51522903, 41772246).
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Yujie, Z., Xiaoli, L. & Enzhi, W. Influence of impoundment gravity and pore pressure on reactivation of faults. Geomech. Geophys. Geo-energ. Geo-resour. 6, 64 (2020). https://doi.org/10.1007/s40948-020-00191-9
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DOI: https://doi.org/10.1007/s40948-020-00191-9