Paleomagnetism and counterclockwise tectonic rotation of the Upper Oligocene Sooke Formation, southern Vancouver Island, British Columbia

Prothero, Donald R.; Draus, Elizabeth; Cockburn, Thomas C. CockburnT.C.; Nesbitt, Elizabeth A.

doi:10.1139/e08-012

Cited by 11 publications

(9 citation statements)

References 27 publications

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“…In northern Cascadia, the forearc region above the subducting slab experiences both interseismic elastic strain induced by partial coupling of the subduction zone interface (e.g., Dragert & Hyndman, 1995; Miller et al., 2001; Savage & Lisowski, 1991), and permanent strain resulting from subduction zone coupling and far‐field tectonic forces (e.g., Delano et al., 2017; Finley et al., 2019; Nelson et al., 2017; Sherrod et al., 2013; Wang et al., 2003; Wells et al., 1998). Permanent forearc deformation is evidenced by instrumental crustal seismicity (e.g., Balfour et al., 2011; Bostock et al., 2019; Brocher et al., 2017; Savard et al., 2018; G. Li et al., 2018), paleoseismic studies of Quaternary‐active forearc faults (Barrie & Greene, 2018; Bennett et al., 2017; Blais‐Stevens et al., 2011; Blakely et al., 2009; Duckworth et al., 2021; Greene & Barrie, 2022; Harrichhausen et al., 2021; Kelsey et al., 2012; Morell et al., 2017, 2018; Nelson et al., 2017; Personius et al., 2014; Schermer et al., 2021), and paleomagnetic, geologic, and geodetic data that show counterclockwise rotation of the Cascadia forearc north of, and margin‐parallel shortening south of, the Strait of JdF (Finley et al., 2019; Mazzotti et al., 2002, 2003; McCaffrey et al., 2007; Miller et al., 2001; Prothero et al., 2008; Wells & McCaffrey, 2013).…”

Section: Tectonic Settingmentioning

confidence: 99%

“…Permanent forearc deformation is evidenced by instrumental crustal seismicity (e.g., Balfour et al, 2011;Bostock et al, 2019;Brocher et al, 2017;Savard et al, 2018;G. Li et al, 2018), paleoseismic studies of Quaternary-active forearc faults (Barrie & Greene, 2018;Bennett et al, 2017;Blais-Stevens et al, 2011;Blakely et al, 2009;Duckworth et al, 2021;Greene & Barrie, 2022;Harrichhausen et al, 2021;Kelsey et al, 2012;Morell et al, 2017Morell et al, , 2018Nelson et al, 2017;Personius et al, 2014;Schermer et al, 2021), and paleomagnetic, geologic, and geodetic data that show counterclockwise rotation of the Cascadia forearc north of, and margin-parallel shortening south of, the Strait of JdF (Finley et al, 2019;Mazzotti et al, 2002Mazzotti et al, , 2003McCaffrey et al, 2007;Miller et al, 2001;Prothero et al, 2008;Wells & McCaffrey, 2013).…”

Section: Tectonic Settingmentioning

confidence: 99%

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Discovery of an Active Forearc Fault in an Urban Region: Holocene Rupture on the XEOLXELEK‐Elk Lake Fault, Victoria, British Columbia, Canada

Harrichhausen,

Finley,

Morell

et al. 2023

Tectonics

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Subduction forearcs are subject to seismic hazard from upper plate faults that are often invisible to instrumental monitoring networks. Identifying active faults in forearcs therefore requires integration of geomorphic, geologic, and paleoseismic data. We demonstrate the utility of a combined approach in a densely populated region of Vancouver Island, Canada, by combining remote sensing, historical imagery, field investigations, and shallow geophysical surveys to identify a previously unrecognized active fault, the XEOLXELEK‐Elk Lake fault, in the northern Cascadia forearc, ∼10 km north of the city of Victoria. Lidar‐derived digital terrain models and historical air photos show a ∼2.5‐m‐high scarp along the surface of a Quaternary drumlinoid ridge. Paleoseismic trenching and electrical resistivity tomography surveys across the scarp reveal a single reverse‐slip earthquake produced a fault‐propagation fold above a blind southwest‐dipping fault. Five geologically plausible chronological models of radiocarbon dated charcoal constrain the likely earthquake age to between 4.7 and 2.3 ka. Fault‐propagation fold modeling indicates ∼3.2 m of reverse slip on a blind, 50° southwest‐dipping fault can reproduce the observed deformation. Fault scaling relations suggest a M 6.1–7.6 earthquake with a 13 to 73‐km‐long surface rupture and 2.3–3.2 m of dip slip may be responsible for the deformation observed in the paleoseismic trench. An earthquake near this magnitude in Greater Victoria could result in major damage, and our results highlight the importance of augmenting instrumental monitoring networks with remote sensing and field studies to identify and characterize active faults in similarily challenging environments.

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Section: Tectonic Settingmentioning

confidence: 99%

Section: Tectonic Settingmentioning

confidence: 99%

Discovery of an Active Forearc Fault in an Urban Region: Holocene Rupture on the XEOLXELEK‐Elk Lake Fault, Victoria, British Columbia, Canada

Harrichhausen,

Finley,

Morell

et al. 2023

Tectonics

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Section: Stratigraphic and Paleogeographic Settingmentioning

confidence: 99%

“…Shallow marine facies of the Sooke Formation at southwestern Vancouver Island are correlated with a reversed magnetozone and Chron C6Cr (latest Oligocene ages, 24.1-24.8 Ma) (Prothero et al, 2008). The Sooke Formation rocks are temporally comparable to the Pysht Formation (23.7-30.5 Ma) in western Washington (e.g., Muller et al, 1981;Brandon et al, 1998;Prothero et al, 2001Prothero et al, , 2008 Jewett Sand (24-25 Ma) in California (Scheirer and Magoon, 2007). These and other Cenozoic sediments were deposited in a fore-arc basin as the Farallon plate (Juan de Fuca plate) subducted beneath the North America plate (e.g., Hyndman et al, 1990;Snavely and Wells, 1996;Brandon et al, 1998).…”

Section: Stratigraphic and Paleogeographic Settingmentioning

confidence: 99%

A new member of the family Plotopteridae (Aves) from the late Oligocene of British Columbia, Canada

Kaiser

Watanabe

Johns

2015

Palaeontologia Electronica

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The discovery of an avian fossil, in the upper Oligocene Sooke Formation rocks on southwestern Vancouver Island, British Columbia, is the first example from Canada of the Plotopteridae, an extinct family that lived in the North Pacific from the late Eocene to the early Miocene. The fossil is a nearly complete, well-preserved coracoid that exhibits the diagnostic features of the family. Stemec suntokum is described as a new genus and species for this family of extinct, wing-propelled diving birds. Coracoids are exceptionally informative bones that lie at the focus of forces acting on the shoulder where they play a major role in avian locomotory biomechanics. The coracoid of Stemec has an unusually narrow, conical shaft that differs fundamentally from the broad, flattened coracoids of other avian groups.

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“…The age of the Sooke Formation at a locality to the southeast of the provenance of this specimen has been estimated to be Chron C6Cr age, 24.1-24.8 Ma, based on recent paleomagnetic studies (Prothero et al, 2008). If this is correct, then the age of this specimen is late Zemorrian (D late Chattian), contemporaneous with other material of Behemotops proteus from the Pysht Formation of Washington State (Domning et al, 1986;Ray et al, 1994) and Oregon (Domning et al, 1986), as well as Behemotops katsuiei and Ashoroa laticosta from Hokkaido, Japan (Saito et al, 1988;Inuzuka, 2000), and Cornwallius sookensis from Unalaska Island, Alaska (Beatty, 2006a;Jacobs et al, 2007), Vancouver Island, British Columbia (Cornwall, 1922;Hay, 1923;Beatty, 2006b), Oregon (Reinhart, 1982;Beatty, 2009), andBaja California Sur, Mexico (VanderHoof, 1942;Applegate, 1986;Beatty et al, 2001).…”

Section: Localitymentioning

confidence: 99%

New insights on the most primitive desmostylian from a partial skeleton ofBehemotops(Desmostylia, Mammalia) from Vancouver Island, British Columbia

Beatty¹,

Cockburn

2015

Journal of Vertebrate Paleontology

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A partial articulated skeleton of a desmostylian was found in siltstone of the Sooke Formation in the streambed at the mouth of the Sombrio River in Juan De Fuca Provincial Park, Vancouver Island, British Columbia, Canada. Another exposure of the Sooke Formation southeast of the locality has been dated to Chron C6Cr age, 24.1-24.8 Ma. This specimen includes the left side of the skull, two molars, a premolar, canines, partial scapula, nearly complete humerus, and numerous vertebrae and ribs. Molar characteristics are the same as material of Behemotops proteus from the Pysht Formation of Washington State, which is near the type locality of Behemotops proteus of the upper Oligocene Pysht Formation, Washington State. Previous specimens of B. proteus were limited to lower jaws and portions of the upper and lower postcanine dentitions. The slightly smaller Behemotops katsuiei from Japan is known from more elements, yet its cranial material is limited to the posterior portion of the cranium and a small portion of the zygomatic arch. This new material allows us to see that Behemotops cf. B. proteus had cranial features much like those seen in Cornwallius sookensis of North America. These include a postorbital process of the jugal, with the zygomatic process of the squamosal not dorsally expanded, a concave hard palate, enlarged canine tusks that point ventrally, and a narrow, curved incisor arcade on a narrow rostrum. This is different from specimens previously referred to as Behemotops emlongi and then synonymized with B. proteus, which have a broad symphysis with large tusks. These specimens formerly known as B. emlongi are now referred to a new genus.http://zoobank.org/urn:lsid:zoobank.

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Paleomagnetism and counterclockwise tectonic rotation of the Upper Oligocene Sooke Formation, southern Vancouver Island, British Columbia

Cited by 11 publications

References 27 publications

Discovery of an Active Forearc Fault in an Urban Region: Holocene Rupture on the XEOLXELEK‐Elk Lake Fault, Victoria, British Columbia, Canada

Discovery of an Active Forearc Fault in an Urban Region: Holocene Rupture on the XEOLXELEK‐Elk Lake Fault, Victoria, British Columbia, Canada

A new member of the family Plotopteridae (Aves) from the late Oligocene of British Columbia, Canada

New insights on the most primitive desmostylian from a partial skeleton ofBehemotops(Desmostylia, Mammalia) from Vancouver Island, British Columbia

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