A new paradigm for large earthquakes in stable continental plate interiors

Large earthquakes within stable continental regions (SCR) show that significant amounts of elastic strain can be released on geological structures far from plate boundary faults, where the vast majority of the Earth's seismic activity takes place. SCR earthquakes show spatial and temporal patterns that differ from those at plate boundaries and occur in regions where tectonic loading rates are negligible. However, in the absence of a more appropriate model, they are traditionally viewed as analogous to their plate boundary counterparts, occurring when the accrual of tectonic stress localized at long‐lived active faults reaches failure threshold. Here we argue that SCR earthquakes are better explained by transient perturbations of local stress or fault strength that release elastic energy from a prestressed lithosphere. As a result, SCR earthquakes can occur in regions with no previous seismicity and no surface evidence for strain accumulation. They need not repeat, since the tectonic loading rate is close to zero. Therefore, concepts of recurrence time or fault slip rate do not apply. As a consequence, seismic hazard in SCRs is likely more spatially distributed than indicated by paleoearthquakes, current seismicity, or geodetic strain rates.

[1]  L. Bollinger,et al.  Evidence for the release of long‐term tectonic strain stored in continental interiors through intraplate earthquakes , 2016 .

[2]  S. Marshak,et al.  Shear velocity structure beneath the central United States: implications for the origin of the Illinois Basin and intraplate seismicity , 2016 .

[3]  T. Kusky,et al.  Stress development in heterogenetic lithosphere: Insights into earthquake processes in the New Madrid Seismic Zone , 2015 .

[4]  Anna H. Olsen,et al.  The 2014 United States National Seismic Hazard Model , 2015 .

[5]  Yuehua Zeng,et al.  Crustal deformation in the New Madrid seismic zone and the role of postseismic processes , 2015 .

[6]  W. Mooney,et al.  Variations of the lithospheric strength and elastic thickness in North America , 2015 .

[7]  R. Roberts,et al.  Microearthquakes illuminate the deep structure of the endglacial Pärvie fault, northern Sweden , 2015 .

[8]  W. Ellsworth,et al.  Increasing seismicity in the U. S. midcontinent: Implications for earthquake hazard , 2015 .

[9]  Å. Fagereng,et al.  Microseismic Activity and Basement Controls on an Active Intraplate Strike‐Slip Fault, Ceres–Tulbagh, South Africa , 2015 .

[10]  H. Jomard,et al.  Fault activity in the epicentral area of the 1580 Dover Strait (Pas-de-Calais) earthquake (northwestern Europe) , 2015 .

[11]  K. Feigl,et al.  Present-day deformation of the Pyrenees revealed by GPS surveying and earthquake focal mechanisms until 2011 , 2015 .

[12]  R. Herrmann,et al.  Earthquake hypocenters and focal mechanisms in central Oklahoma reveal a complex system of reactivated subsurface strike‐slip faulting , 2015 .

[13]  W. Peltier,et al.  Space geodesy constrains ice age terminal deglaciation: The global ICE‐6G_C (VM5a) model , 2015 .

[14]  M. Leonard,et al.  Do Australian intraplate faults generate characteristic earthquakes? , 2015 .

[15]  Wei Wang,et al.  Crustal deformation on the Chinese mainland during 1998–2014 based on GPS data , 2015 .

[16]  É. Calais,et al.  Strain accumulation in the New Madrid and Wabash Valley seismic zones from 14 years of continuous GPS observation , 2014 .

[17]  D. Chambers,et al.  GRACE, time-varying gravity, Earth system dynamics and climate change , 2014, Reports on progress in physics. Physical Society.

[18]  S. Mitra,et al.  Active faulting in apparently stable peninsular India: Rift inversion and a Holocene‐age great earthquake on the Tapti Fault , 2014 .

[19]  H. Steffen,et al.  A GPS velocity field for Fennoscandia and a consistent comparison to glacial isostatic adjustment models , 2014 .

[20]  S. Ge,et al.  Sharp increase in central Oklahoma seismicity since 2008 induced by massive wastewater injection , 2014, Science.

[21]  B. E. Shaw,et al.  Uniform California Earthquake Rupture Forecast, Version 3 (UCERF3)—The Time‐Independent Model , 2014 .

[22]  H. Koyi,et al.  Major earthquake at the Pleistocene-Holocene transition in Lake Vättern, southern Sweden , 2014 .

[23]  Colby A. Smith,et al.  Surficial geology indicates early Holocene faulting and seismicity, central Sweden , 2014, International Journal of Earth Sciences.

[24]  S. Horton,et al.  Earthquake Focal Mechanisms in the New Madrid Seismic Zone , 2014 .

[25]  Patrick Wu,et al.  The effect of earth rheology and ice-sheet size on fault slip and magnitude of postglacial earthquakes , 2014 .

[26]  S. Hough,et al.  The New Madrid Seismic Zone: Not Dead Yet , 2014, Science.

[27]  S. Stein,et al.  Long aftershock sequences in North China and Central US: implications for hazard assessment in mid-continents , 2014 .

[28]  R. Madole Stratigraphic evidence of Holocene faulting in the midcontinent , 2014 .

[29]  D. Sandwell,et al.  Is there a discrepancy between geological and geodetic slip rates along the San Andreas Fault System , 2013 .

[30]  Karl Zippelt,et al.  Recent surface displacements in the Upper Rhine Graben — Preliminary results from geodetic networks , 2013 .

[31]  F. Cappa,et al.  Tracking fluid pressure buildup from focal mechanisms during the 2003–2004 Ubaye seismic swarm, France , 2013 .

[32]  G. Abers,et al.  Potentially induced earthquakes in Oklahoma, USA: Links between wastewater injection and the 2011 Mw 5.7 earthquake sequence , 2013 .

[33]  P. Tregoning,et al.  A decade of horizontal deformation from great earthquakes , 2013 .

[34]  Kris Vanneste,et al.  A Model of Composite Seismic Sources for the Lower Rhine Graben, Northwest Europe , 2013 .

[35]  Z. Altamimi,et al.  A new velocity field for Africa from combined GPS and DORIS space geodetic Solutions: Contribution to the definition of the African reference frame (AFREF) , 2013 .

[36]  Timothy E. Dawson,et al.  Uniform California earthquake rupture forecast, version 3 (UCERF3): the time-independent model , 2013 .

[37]  M. Zoback,et al.  Intraplate earthquakes, regional stress and fault mechanics in the Central and Eastern U.S. and Southeastern Canada , 2012 .

[38]  J. Nocquet Present-day kinematics of the Mediterranean: A comprehensive overview of GPS results , 2012 .

[39]  Kristy F. Tiampo,et al.  The 2011 Lorca earthquake slip distribution controlled by groundwater crustal unloading , 2012 .

[40]  Dan Clark,et al.  Long-term behaviour of Australian stable continental region (SCR) faults , 2012 .

[41]  Ali Karrech,et al.  Thermal‐elastic stresses and the criticality of the continental crust , 2012 .

[42]  M. Zoback,et al.  Regional Stress Orientations and Slip Compatibility of Earthquake Focal Planes in the New Madrid Seismic Zone , 2012 .

[43]  S. Stein,et al.  Mineral, Virginia, earthquake illustrates seismicity of a passive‐aggressive margin , 2012 .

[44]  Paul L. Joskow,et al.  The Future of Nuclear Power After Fukushima , 2012 .

[45]  R. Herrmann,et al.  Monitoring the Earthquake source process in North America , 2011 .

[46]  U. Hugentobler,et al.  Estimation of velocity uncertainties from GPS time series: Examples from the analysis of the South African TrigNet network , 2011 .

[47]  D. Marsan,et al.  Strain localization and fluid migration from earthquake relocation and seismicity analysis in the western Vosges (France) , 2011 .

[48]  S. Stein,et al.  2000 years of migrating earthquakes in North China: How earthquakes in midcontinents differ from those at plate boundaries , 2011 .

[49]  J. K. Costain,et al.  Review: Research Results in Hydroseismicity from 1987 to 2009 , 2010 .

[50]  D. Sandwell,et al.  Ocean loading effects on stress at near shore plate boundary fault systems , 2010 .

[51]  É. Calais,et al.  Triggering of New Madrid seismicity by late-Pleistocene erosion , 2010, Nature.

[52]  Hans-Georg Scherneck,et al.  Recent results based on continuous GPS observations of the GIA process in Fennoscandia from BIFROST , 2010 .

[53]  C. Pascal,et al.  Tectonic significance of present-day stress relief phenomena in formerly glaciated regions , 2010, Journal of the Geological Society.

[54]  Andreas Barth,et al.  Global crustal stress pattern based on the World Stress Map database release 2008 , 2010 .

[55]  S. Stein,et al.  Long aftershock sequences within continents and implications for earthquake hazard assessment , 2009, Nature.

[56]  Frédéric Cappa,et al.  Modeling crustal deformation and rupture processes related to upwelling of deep CO2-rich fluids during the 1965-1967 Matsushiro Earthquake Swarm in Japan , 2009 .

[57]  S. Stein,et al.  Mid-Continent Earthquakes as a Complex System , 2009 .

[58]  S. Stein,et al.  Time-Variable Deformation in the New Madrid Seismic Zone , 2009, Science.

[59]  S. White,et al.  Pleistocene to Recent rejuvenation of the Hebron Fault, SW Namibia , 2009 .

[60]  R. Lagerbäck,et al.  Early Holocene faulting and paleoseismicity in northern Sweden , 2009 .

[61]  Zhen Liu,et al.  Stresses that drive the plates from below: Definitions, computational path, model optimization, and error analysis , 2008 .

[62]  Amr S. Elnashai,et al.  Impact of Earthquakes on the Central USA , 2008 .

[63]  A. Hampel,et al.  Effect of ice sheet growth and melting on the slip evolution of thrust faults , 2008 .

[64]  T. Lecocq Earthquake relocation in the Ardenne (Belgium): identification of active structures in intraplate context , 2008 .

[65]  O. Heidbach,et al.  Plate boundary forces are not enough: Second‐ and third‐order stress patterns highlighted in the World Stress Map database , 2007 .

[66]  J. Avouac,et al.  Seasonal variations of seismicity and geodetic strain in the Himalaya induced by surface hydrology as revealed from GPS monitoring, seismic monitoring and GRACE measurements , 2007 .

[67]  J. Avouac,et al.  Seasonal modulation of seismicity in the Himalaya of Nepal , 2007 .

[68]  Michael R. Craymer,et al.  Observation of glacial isostatic adjustment in “stable” North America with GPS , 2007 .

[69]  M. Everaerts,et al.  Relevance of active faulting and seismicity studies to assessments of long-term earthquake activity and maximum magnitude in intraplate northwest Europe, between the Lower Rhine Embayment and the North Sea , 2007 .

[70]  É. Calais,et al.  Continental deformation in Asia from a combined GPS solution , 2006 .

[71]  Y. Bock,et al.  Modulation of the earthquake cycle at the southern San Andreas fault by lake loading , 2006 .

[72]  R. Bilham,et al.  Great Himalayan earthquakes and the Tibetan plateau , 2006, Nature.

[73]  Robert B. Smith,et al.  Contemporary deformation of the Wasatch Fault, Utah, from GPS measurements with implications for interseismic fault behavior and earthquake hazard: Observations and kinematic analysis , 2006 .

[74]  Heiner Igel,et al.  Evidence for rainfall‐triggered earthquake activity , 2006 .

[75]  Tammy M. Rittenour,et al.  Stratigraphic evidence for millennial-scale temporal clustering of earthquakes on a continental-interior fault: Holocene Mississippi River floodplain deposits, New Madrid seismic zone, USA , 2006 .

[76]  J. Nocquet,et al.  Seismology: Tectonic strain in plate interiors? , 2005, Nature.

[77]  T. James,et al.  GPS crustal strain, postglacial rebound, and seismic hazard in eastern North America: The Saint Lawrence valley example , 2005 .

[78]  N. Mörner An interpretation and catalogue of paleoseismicity in Sweden , 2005 .

[79]  S. Stein,et al.  Dependence of Possible Characteristic Earthquakes on Spatial Sampling: Illustration for the Wasatch Seismic Zone, Utah , 2005 .

[80]  M. Ellis,et al.  Space geodetic evidence for rapid strain rates in the New Madrid seismic zone of central USA , 2005, Nature.

[81]  W. Mooney,et al.  An updated global earthquake catalogue for stable continental regions: reassessing the correlation with ancient rifts , 2005 .

[82]  Ralf Hetzel,et al.  Slip rate variations on normal faults during glacial–interglacial changes in surface loads , 2005, Nature.

[83]  Jean-Mathieu Nocquet,et al.  Geodetic constraints on glacial isostatic adjustment in Europe , 2005 .

[84]  M. Andreoli,et al.  Offshore mud volcanoes and onland faulting in southwestern Africa: neotectonic implications and constraints on the regional stress field , 2005 .

[85]  S. Schmid,et al.  Evolution of the European Cenozoic Rift System: interaction of the Alpine and Pyrenean orogens with their foreland lithosphere , 2004 .

[86]  Susan E. Hough,et al.  Analysing the 1811–1812 New Madrid earthquakes with recent instrumentally recorded aftershocks , 2004, Nature.

[87]  J. Nocquet,et al.  Geodetic Measurements of Crustal Deformation in the Western Mediterranean and Europe , 2004 .

[88]  Jan M. Johansson,et al.  Continuous GPS measurements of postglacial adjustment in Fennoscandia: 2. Modeling results: FENNOSCANDIAN GPS MODELING RESULTS , 2004 .

[89]  M. Machette,et al.  Paleoseismicity of Two Historically Quiescent Faults in Australia: Implications for Fault Behavior in Stable Continental Regions , 2003 .

[90]  J. Nocquet,et al.  Crustal velocity field of western Europe from permanent GPS array solutions, 1996–2001 , 2003 .

[91]  James L. Davis,et al.  Comparison of geodetic and geologic data from the Wasatch region, Utah, and implications for the spectral character of Earth deformation at periods of 10 to 10 million years , 2003 .

[92]  K. Heki Snow load and seasonal variation of earthquake occurrence in Japan , 2003 .

[93]  K. Lambeck,et al.  Glacial Rebound and Crustal Stress in Finland , 2003 .

[94]  Michael Bevis,et al.  Motion and rigidity of the Pacific Plate and implications for plate boundary deformation , 2002 .

[95]  Robert H. Lafferty,et al.  The Earthquake Potential of the New Madrid Seismic Zone , 2002 .

[96]  J. Johansson,et al.  Continuous GPS measurements of postglacial adjustment in Fennoscandia 1. Geodetic results , 2002 .

[97]  Paleoseismic investigations along the Peel Boundary Fault: geological setting, site selection and trenching results , 2002, Netherlands Journal of Geosciences - Geologie en Mijnbouw.

[98]  J Johansson Continuous GPS measurement of postglacial adjustment in Fennoscandia, 1. , 2002 .

[99]  E. Paulissen,et al.  The Deposition History of the Coversands along the Bree Fault Escarpment, NE Belgium , 2001, Netherlands Journal of Geosciences.

[100]  F. Pollitz,et al.  Sinking Mafic Body in a Reactivated Lower Crust: A Mechanism for Stress Concentration at the New Madrid Seismic Zone , 2001 .

[101]  A. Špičák,et al.  Possible role of fluids in the process of earthquake swarm generation in the West Bohemia/Vogtland seismoactive region , 2001 .

[102]  K. Bräuer,et al.  Transport of mantle volatiles through the crust traced by seismically released fluids: a natural experiment in the earthquake swarm area Vogtland/NW Bohemia, Central Europe , 2001 .

[103]  E. Paulissen,et al.  Surface-rupturing history of the Bree fault scarp, Roer Valley graben: Evidence for six events since the late Pleistocene , 2001 .

[104]  Hiroo Kanamori,et al.  The physics of earthquakes , 2001 .

[105]  M. Zoback,et al.  Did deglaciation trigger intraplate seismicity in the New Madrid seismic zone , 2001 .

[106]  S. Hough,et al.  On the Modified Mercalli intensities and magnitudes of the 1811–1812 New Madrid earthquakes , 2000 .

[107]  Kenner,et al.  A mechanical model for intraplate earthquakes: application to the new madrid seismic zone , 2000, Science.

[108]  P. Johnston,et al.  Can deglaciation trigger earthquakes in N. America? , 2000 .

[109]  M. Zoback,et al.  How faulting keeps the crust strong , 2000 .

[110]  M. Machette,et al.  Active, capable, and potentially active faults — a paleoseismic perspective , 2000 .

[111]  R. V. Arsdale Displacement history and slip rate on the Reelfoot fault of the New Madrid seismic zone , 2000 .

[112]  K. Lambeck,et al.  Postglacial rebound and fault instability in Fennoscandia , 1999 .

[113]  Pradeep Talwani,et al.  Fault geometry and earthquakes in continental interiors , 1999 .

[114]  Newman,et al.  Slow deformation and lower seismic hazard at the new madrid seismic zone , 1999, Science.

[115]  M. Greene,et al.  OVERVIEW OF THE MAHARASHTRA , INDIA EMERGENCY EARTHQUAKE REHABILITATION PROGRAM , 1999 .

[116]  Thierry Camelbeeck,et al.  Geological and geophysical evidence for large palaeo-earthquakes with surface faulting in the Roer Graben (northwest Europe) , 1998 .

[117]  Anthony J. Crone,et al.  Episodic nature of earthquake activity in stable continental regions revealed by palaeoseismicity studies of Australian and North American quaternary faults , 1997 .

[118]  A. Crone,et al.  Late Quaternary surface faulting on the Cheraw Fault, southeastern Colorado , 1997 .

[119]  M. Gölke,et al.  ORIGINS OF THE EUROPEAN REGIONAL STRESS FIELD , 1996 .

[120]  R. Arvidsson Fennoscandian Earthquakes: Whole Crustal Rupturing Related to Postglacial Rebound , 1996, Science.

[121]  S. Stein,et al.  How rigid is the stable interior of the North American Plate , 1996 .

[122]  T. Camelbeeck,et al.  Large earthquake in northern Europe more likely than once thought , 1996 .

[123]  A. Johnston Seismic moment assessment of earthquakes in stable continental regions—III. New Madrid 1811–1812, Charleston 1886 and Lisbon 1755 , 1996 .

[124]  J. Dieterich,et al.  Role of stress triggering in earthquake migration on the North Anatolian fault , 1996 .

[125]  D. Argus,et al.  Tests of the rigid-plate hypothesis and bounds on intraplate deformation using geodetic data from very long baseline interferometry , 1996 .

[126]  J. McCalpin,et al.  Holocene paleoseismicity, temporal clustering, and probabilities of future large (M > 7) earthquakes on the Wasatch fault zone, Utah , 1996 .

[127]  M. Zoback,et al.  Stress perturbation associated with the Amazonas and other ancient continental rifts , 1996 .

[128]  Arch C. Johnston,et al.  Seismic moment assessment of earthquakes in stable continental regions—II. Historical seismicity , 1996 .

[129]  A. Johnston Seismic moment assessment of earthquakes in stable continental regions—I. Instrumental seismicity , 1996 .

[130]  J. Pechmann,et al.  The Problem of the Random Earthquake in Seismic Hazard Analysis: Wasatch Front Region, Utah , 1995 .

[131]  K. Coppersmith,et al.  The earthquakes of stable continental regions. Volume 2: Appendices A to E. Final report , 1994 .

[132]  A. Bent The 1989 (MS 6.3) Ungava, Quebec, earthquake: a complex intraplate event , 1994 .

[133]  A. Johnston,et al.  The earthquakes of stable continental regions , 1994 .

[134]  M. Zoback,et al.  Upper-crustal strength inferred from stress measurements to 6 km depth in the KTB borehole , 1993, Nature.

[135]  Jian Lin,et al.  Change in Failure Stress on the Southern San Andreas Fault System Caused by the 1992 Magnitude = 7.4 Landers Earthquake , 1992, Science.

[136]  M. Zoback,et al.  Rapid Intraplate Strain Accumulation in the New Madrid Seismic Zone , 1992, Science.

[137]  Larry G. Mastin,et al.  Regional patterns of tectonic stress in Europe , 1992 .

[138]  R. Lagerbäck Dating of Late Quaternary faulting in northern Sweden , 1992, Journal of the Geological Society.

[139]  Thomas C. Hanks,et al.  Common features of the excitation and propagation of strong ground motion for North American earthquakes , 1992 .

[140]  M. Machette,et al.  Geologic investigations of the 1986 Marryat Creek, Australia, earthquake; implications for paleoseismicity in stable continental regions , 1992 .

[141]  H. Hasegawa,et al.  The first surface faulting from a historical intraplate earthquake in North America , 1991, Nature.

[142]  A. Crone,et al.  Style and Timing of Holocene Surface Faulting on the Meers Fault, Southwestern Oklahoma , 1990 .

[143]  P. Basham,et al.  Earthquakes at North-Atlantic passive margins : neotectonics and postglacial rebound , 1989 .

[144]  R. Wood Extraordinary Deglaciation Reverse Faulting in Northern Fennoscandia , 1989 .

[145]  S. Stein,et al.  Passive Margin Earthquakes, Stresses and Rheology , 1989 .

[146]  M. Zoback,et al.  Chapter 24: Tectonic stress field of the continental United States , 1989 .

[147]  A. Johnston The Seismicity of ‘Stable Continental Interiors’ , 1989 .

[148]  M. Zoback,et al.  Tectonic stress field of the con-tinental United States , 1989 .

[149]  C. Scholz,et al.  Two types of reservoir-induced seismicity , 1988 .

[150]  L. Long A Model for Major Intraplate Continental Earthquakes , 1988 .

[151]  R. Madole Stratigraphic evidence of Holocene faulting in the mid-continent: The Meers fault, southwestern Oklahoma , 1988 .

[152]  H. Gupta The present status of reservoir induced seismicity investigations with special emphasis on Koyna earthquakes , 1985 .

[153]  W. Prescott,et al.  Evidence for lower crustal ductile strain localization in southern New York , 1985, Nature.

[154]  D. P. Schwartz,et al.  Fault behavior and characteristic earthquakes: Examples from the Wasatch and San Andreas Fault Zones , 1984 .

[155]  C. Froidevaux,et al.  Tectonic stresses in the lithosphere , 1983 .

[156]  M. Zoback,et al.  State of stress and intraplate earthquakes in the United States. , 1981, Science.

[157]  B. Hoffers,et al.  Stress pattern and strain release in the Alpine foreland , 1981 .

[158]  L. Sykes Intraplate seismicity, reactivation of preexisting zones of weakness, alkaline magmatism, and other tectonism postdating continental fragmentation , 1978 .

[159]  D. L. Campbell Investigation of the stress‐concentration mechanism for intraplate earthquakes , 1978 .

[160]  M. L. Sbar,et al.  Seismicity and lithospheric stress in New York and adjacent areas , 1977 .

[161]  D. Simpson Seismicity changes associated with reservoir loading , 1976 .

[162]  L. Ahorner,et al.  Present-day stress field and seismotectonic block movements along major fault zones in Central Europe , 1975 .

[163]  M. L. Sbar,et al.  Intraplate Earthquakes, Lithospheric Stresses and the Driving Mechanism of Plate Tectonics , 1973, Nature.

[164]  O. Nuttli,et al.  The Mississippi Valley earthquakes of 1811 and 1812: Intesities, ground motion and magnitudes , 1973, Bulletin of the Seismological Society of America.