An Ancient Rift Complex and its relation to contemporary seismicity in the New Madrid Seismic Zone

Braile, L. W.; Keller, G. Randy; Hinze, William J.; Lidiak, Edward G.

doi:10.1029/tc001i002p00225

Cited by 104 publications

(56 citation statements)

References 22 publications

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“…The most spectacular examples are the Reelfoot Rift in the U.S. (associated with the M w 7.2-8.1 1811-1812 New Madrid earthquakes, see e.g. Braile et al, 1982), and the Kutch Rift in India (associated with the M w 7.7 1819 Rann of Kutch and M w 7.6 2001 Buhj earthquakessee Bilham, 1999 andRastogi et al, 2001, resp. ).…”

Section: Scr Paleorifts Elsewherementioning

confidence: 96%

Localization of intraplate deformation through fluid-assisted faulting in the lower-crust: The Flinders Ranges, South Australia

et al. 2015

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Section: Scr Paleorifts Elsewherementioning

confidence: 96%

Localization of intraplate deformation through fluid-assisted faulting in the lower-crust: The Flinders Ranges, South Australia

et al. 2015

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“…The Mississippi embayment is a southwest plunging trough of late Cretaceous and Tertiary age (Stearns, 1957;Pryor, 1960). Formation of the Mississippi embayment has been attributed to the opening of the Gulf of Mexico and reactivation of the underlying late Precambrian to Cambrian Reelfoot rift (Burke and Dewey, 1973;Ervin and McGinnis, 1975;Kane et al, 1981;Braile et al, 1982). However, Cox and Van Arsdale (1997) argue that the Mississippi embayment formed as a consequence of plate tectonic drifting of the Mississippi Valley over the Bermuda hotspot in the Late Cretaceous.…”

Section: Introductionmentioning

confidence: 94%

Late Cretaceous and Cenozoic Geology of the New Madrid Seismic Zone

Arsdale¹,

TenBrink²

2000

Bulletin of the Seismological Society of America

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“…The Western Ontario seismic zone is aligned with an aeromagnetic structure adjacent to and west of the Niagara-Pickering magnetic lineament and may be in a similar relation to the Coshocton zone as the Akron lineament. The association between seismicity and prominent Precambrian structures persists west of the study area, where the Anna seismic zone is spatially associated with the Grenville Front {e.g., Braile et al, 1982).…”

Section: Grenville-age Sutures Associatedmentioning

confidence: 99%

“…Then, we compare known structural features with seismicity patterns which are apparent in the revised earthquake data. Although correlation between structure and intracratonic earthquakes has been generally elusive, with improved resolution examples are now beginning to appear (e.g., Braile et al, 1982;Adams et al, 1991;Dawers and Seeber, 1991). We are particularly interested in characterizing the kind of structures that may be reactivated in the current tectonic stress regime (e.g., Sbar and Sykes, 1973;Zoback and Zoback, 1989) and to test the hypothesis that structures of any age may be pertinent to intracratonic seismogenesis.…”

Section: Introductionmentioning

confidence: 99%

Natural and Induced Seismicity in the Lake Erie-Lake Ontario Region: Reactivation of Ancient Faults with Little Neotectonic Displacement

Seeber¹,

Armbruster²

2007

gpq

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The two most prominent seismic zones in the Lake Erie-Lake Ontario region are associated with the Akron magnetic lineament and with the Clarendon-Linden fault. Both these features are recognized from geophysical data as regional basement structures related to the Grenville collisional orogen. Neotectonic displacement is not geologically evident, although Paleozoic reactivation is manifested by the Clarendon-Linden fault. We have sharpened the definition of seismic zones in the region by introducing newly discovered events, improving constraints on locations and size for many others, and omitting unreliable ones. This seismicity tends to occur on old faults with minor neotectonic displacements. Related conclusions are: 1) neotectonic surface displacement is not necessary for fault capability, 2) seismogenic faults may have geological and/or geophysical expressions, and 3) a stationary moment release at the historic level requires more capable faults than the ones active during the historic period. Waste fluid injection, oil recovery, and salt-brine recovery have been implicated in cases of induced seismicity in the study area and might have contributed a significant portion of the known earthquakes. Fluid is being injected into the basal platform formation at a depth of 1.8 km near Ashtabula, Ohio. In July 1987, about a year after the onset of injection, a mbLg=3.8 main shock occurred within a 60 km wide area with no known prior seismicity. Aftershocks detected by a short-term local seismic network define a vertical left-lateral fault in the basement just below the platform rocks as close as 700 m from the injection well, probably a reactivated pre-existing fault. Subsequent seismicity suggests a westward migration by 5-10 km, possibly along the same fault.

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An Ancient Rift Complex and its relation to contemporary seismicity in the New Madrid Seismic Zone

Cited by 104 publications

References 22 publications

Localization of intraplate deformation through fluid-assisted faulting in the lower-crust: The Flinders Ranges, South Australia

Localization of intraplate deformation through fluid-assisted faulting in the lower-crust: The Flinders Ranges, South Australia

Late Cretaceous and Cenozoic Geology of the New Madrid Seismic Zone

Natural and Induced Seismicity in the Lake Erie-Lake Ontario Region: Reactivation of Ancient Faults with Little Neotectonic Displacement

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