A New Appraisal of Lithospheric Structures of the Cordillera‐Craton Boundary Region in Western Canada

Chen, Yunfeng; Gu, Yu Jeffrey; Hung, S.

doi:10.1029/2018tc004956

Cited by 12 publications

(14 citation statements)

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“…We detect upper crustal LVZs in central Alberta, which were suggested earlier through independent analyses of receiver functions (Chen et al, ) and noise correlation tomography (Gu & Shen, ). These basin‐scale LVZs are rarely observed in stable cratons, and their presence could signify residual imprints of ancient orogenic processes surrounding the STZ and Vulcan Structure (Chen et al, , ; Gu et al, ). Low isotropic velocities of similar strengths in the mid‐to‐lower crust beneath the Cordillera are further suggested by ambient noise data (Dalton et al, ), which contrasts with the moderately high velocities of the upper crust in the intact Archean and Proterozoic accreted domains.…”

Section: Discussionmentioning

confidence: 99%

“…This extensive deformation history is highlighted by the presence of three proposed tectonic discontinuities known as the Great Slave Lake Shear Zone, Snowbird Tectonic Zone (STZ), and Vulcan Structure (Figure ), respectively, from north to south. We refer the reader to a more detailed review of the regional tectonics (Chen et al, ; Gu et al, ).…”

Section: Tectonic Setting and Previous Geophysical Surveysmentioning

confidence: 99%

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Shear Velocity and Radial Anisotropy beneath Southwestern Canada: Evidence for Crustal Extension and Thick‐Skinned Tectonics

Wang

Chen

2020

JGR Solid Earth

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Deformation‐associated craton assembly and Cordilleran orogenesis played major roles during the crustal formation beneath the western margin of North America. To improve the understanding of the deformation history in this region, we investigate the crustal shear velocity and anisotropy by analyzing fundamental mode Rayleigh and Love waves from ambient seismic noise. Continuous recordings from 118 regional broadband stations reveal lateral variations in both velocity and anisotropy with strong spatial affinities to major geological domains. Strong variations in radial anisotropy, which dips westward and extends to at least midcrustal depths, suggest a “thick‐skinned” foreland thrust‐and‐fold belt beneath the Canadian Rocky Mountains. Our regional data also suggest increased horizontal shear velocities beneath the southern Canadian Cordillera, particularly near the Omineca Belt, which may have resulted from strong zonal deformation within the Cordilleran crust. This anisotropic anomaly migrates southward, and its spatial extent agrees well with the normal fault distribution to the west of the Rocky Mountain Trench. Our observations offer new evidence for the Eocene extension of the orogenic hinterland during the trans‐tensional motion of the Cordillera to the North American craton.

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Section: Discussionmentioning

confidence: 99%

Section: Tectonic Setting and Previous Geophysical Surveysmentioning

confidence: 99%

Shear Velocity and Radial Anisotropy beneath Southwestern Canada: Evidence for Crustal Extension and Thick‐Skinned Tectonics

Wang

Chen

2020

JGR Solid Earth

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“…Furthermore, fast-axis orientations remain parallel to the faults at uppermost mantle depths suggesting that Journal of Geophysical Research: Solid Earth 10.1029/2019JB018837 the Tintina and the Denali Faults shear features extend well into the NCC lithosphere (Audet et al, 2016;McLellan et al, 2018), but such studies do not yet fully incorporate seismic data from the EarthScope USArray-Transportable Array stations across Alaska and Yukon. Seismic tomography at various resolution scales generally reveals low seismic velocities within the Cordillera lithosphere transitioning to high velocities within the cratonic lithosphere across a boundary roughly coinciding with the surface expression of the Rocky Mountain Trench, which is the southern extension of the Tintina Fault in the Southern Canadian Cordillera (Bao et al, 2014;Bedle & van der Lee, 2009;Chen et al, 2018;Frederiksen et al, 1998Frederiksen et al, , 2001McLellan et al, 2018;Mercier et al, 2009;Schaeffer & Lebedev, 2014;van der Lee & Frederiksen, 2005;Zaporozan et al, 2018). Regional seismic tomography studies conducted over Alaska, USA, show numerous details on the underlying lithosphere.…”

Section: 1029/2019jb018837mentioning

confidence: 99%

The Upper Mantle Structure of Northwestern Canada From Teleseismic Body Wave Tomography

et al. 2020

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The Northern Canadian Cordillera (NCC) is an actively deforming orogenic belt in northwestern Canada. Geochemical and geophysical data show that the NCC is underlain by a thin and hot lithosphere, in contrast with the adjacent cold and thick cratonic lithosphere to the east. This juxtaposition of cold/hot and thick/thin lithosphere across a narrow transition zone has important implications for regional geodynamics. The recent deployment of USArray Transportable Array and other seismic stations across Alaska, USA, and northwestern Canada allows us to image lithosphere and upper mantle three‐dimensional seismic velocity structure at significantly improved resolution. Our model reveals a broad high‐velocity anomaly across northern Yukon and Northwest Territories, which is interpreted as buried cratonic lithosphere and which we refer to as the Mackenzie craton. Another prominent high‐velocity anomaly is imaged beneath northeastern British Columbia and is interpreted to indicate cratonic lithosphere beneath the Northern Rocky Mountains. These two mechanically strong lithospheric blocks, also suggested by regional magnetic data, are interpreted to buttress the ends of the Mackenzie Mountains fold and thrust belt, guiding intervening cordilleran mantle flow toward the Canadian Shield and controlling the arcuate geometry of the Mackenzie Mountains fold and thrust belt. Both P and S wave models also reveal the signature of a northward dipping, subducting Wrangell slab across the southern region of the Alaska/Yukon border. Strong P and S wave velocity contrasts across the Tintina Fault suggest that it is a lithosphere‐scale shear zone that extends into the upper mantle beneath the NCC and demarcates distinct regions of lithospheric mantle.

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“…Over the past few decades, the Alberta Basin has been one of the most intensively studied regions thanks to oil and gas exploration, Lithoprobe active-source experiments (e.g., Clowes et al, 2002;Cook, 1995;Eaton et al, 2000;Gorman et al, 2002;Hope et al, 1999;Ross et al, 2000), and, more recently, broadband seismic surveys (Bao & Eaton, 2015;Chen et al, 2015;Dalton et al, 2011;Gu et al, 2011Gu et al, , 2015Gu et al, , 2018. These studies offer compelling evidence for intricate domains below the sedimentary basin, which largely support an earlier-proposed regional Proterozoic tectonic framework (e.g., Pilkington et al, 2000;Ross et al, 1991;Villeneuve et al, 1993) and a Cenozoic sharp structural gradient from the stable continental cratons east of the Alberta Basin to the Canadian Cordillera (e.g., Chen et al, 2017Chen et al, , 2018Nettles & Dziewoński, 2008;van der Lee & Frederiksen, 2005). Recent seismological evidence further suggests that much of the past and ongoing deformation has been engraved onto the underlying lithosphere and upper mantle, contributing to mantle fabrics that are largely parallel to the present-day absolute plate motion (APM) directions based on surface wave tomography (e.g., Bao et al, 2016;Gung et al, 2003;Marone & Romanowicz, 2007;Yuan & Romanowicz, 2010) and shear wave splitting observations (e.g., Bastow et al, 2011;Courtier et al, 2010;Currie et al, 2004;Gu et al, 2011;Liu et al, 2014;Shragge et al, 2002).…”

Section: Previous Geophysical Studies and Seismic Anisotropymentioning

confidence: 65%

“…Since early 2006, the regional seismic station coverage in Alberta has improved substantially through the establishment of the Canadian Rockies and Alberta Network (hereafter CRANE), the first semiuniform broadband seismic array in Alberta and parts of Saskatchewan, Canada (Gu et al, ). Continuous seismic signals from this array have laid the groundwork for a number of recent findings pertaining to regional seismicity and crust/mantle structures (e.g., Bao et al, ; Chen et al, , ; Gu et al, ), some of which are considered in this analysis for the assessment of past and ongoing lithosphere deformation processes beneath the Alberta Basin.…”

Section: Introductionmentioning

confidence: 99%

Shear Wave Splitting Discloses Two Episodes of Collision‐Related Convergence in Western North America

Chen

et al. 2019

JGR Solid Earth

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Seismic anisotropy imposes first‐order constraints on the strain history of crust and upper mantle rocks. In this study, we analyze the mantle seismic anisotropy of the Western Canada Sedimentary Basin using a new shear wave spitting data set consisting of 1,333 teleseismic arrivals from 82 seismic stations. The resulting 332 high‐quality measurements yield a regional mean apparent splitting time (i.e., the magnitude of anisotropy) of 1.1 ± 0.3 s and an average fast orientation (i.e., the direction of anisotropy) of 54.6° ± 17.2°, which favor a two‐layer anisotropic model based on the 90° back azimuthal periodicity in both parameters. The northeast trending fast orientations dominate the lower layer at lithospheric depths and are approximately parallel to the present‐day absolute plate motions (APMs; i.e., <35°) due to the active asthenospheric flow. On the other hand, deviations from the APMs along the Canadian Rocky Mountain foothills could reflect disrupted mantle flow surrounding a southwestward migrating cratonic lithosphere. Also revealed are two elongated upper‐layer anisotropic anomalies in the lithosphere that are spatially correlated with Moho depths. Their characteristics suggest frozen‐in anisotropy imprinted along two convergent boundaries: (1) the Paleoproterozoic Snowbird Tectonic Zone that separates northeast (north) from northwest (south) fast directions and (2) the foothills of the Rocky Mountains that exhibit northeast trending orientations consistent with those of the APMs, maximum crustal stress, and electromagnetic anisotropy. Compressions associated with the Cordilleran orogenesis could be responsible for the spatial changes in the shear wave anisotropy from the foothills to the cratonic interior.

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A New Appraisal of Lithospheric Structures of the Cordillera‐Craton Boundary Region in Western Canada

Cited by 12 publications

References 118 publications

Shear Velocity and Radial Anisotropy beneath Southwestern Canada: Evidence for Crustal Extension and Thick‐Skinned Tectonics

Shear Velocity and Radial Anisotropy beneath Southwestern Canada: Evidence for Crustal Extension and Thick‐Skinned Tectonics

The Upper Mantle Structure of Northwestern Canada From Teleseismic Body Wave Tomography

Shear Wave Splitting Discloses Two Episodes of Collision‐Related Convergence in Western North America

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