The Sask Craton and Hearne Province margin: seismic reflection studies in the western Trans-Hudson Orogen

Hajnal, Z.; Lewry, John F.; White, Don; Ashton, K; Clowes, Ron M.; Stauffer, Mel R.; Györfi, I.; Takács, E.

doi:10.1139/e05-026

Cited by 56 publications

(33 citation statements)

References 29 publications

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“…Continental arc formation due to pre‐collision convergence and ocean‐basin closure is represented by the giant Wathamun‐Chipewyan batholith. Where exposed adjacent to Hudson Bay, the THO contains both juvenile supracrustal domains as well as blocks of pre 1.91 Ga crust, such as the Archean Sask craton [ Hajnal et al , 2005]. The lithospheric mantle beneath Hudson Bay has high shear velocity and is estimated to be at least 200 km in thickness, characteristics that are typical of Archean mantle keels [ Darbyshire and Eaton , 2010].…”

Section: Tectonic Settingmentioning

confidence: 99%

Crustal anisotropy beneath Hudson Bay from ambient noise tomography: Evidence for post‐orogenic lower‐crustal flow?

Pawlak¹,

Eaton²,

Darbyshire³

et al. 2012

J. Geophys. Res.

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The crust underlying Hudson Bay, Canada records a long and complex tectonic history. In this study, we investigate this region using tomographic inversion based on continuous ambient noise recordings from 37 broadband seismograph stations that encircle Hudson Bay. The ambient noise data were processed to obtain group‐velocity dispersion measurements from 10–35 s period, which were inverted using an algorithm that incorporates the effects of anisotropy. This work is among the first in which ambient noise data have been used to investigate azimuthal anisotropy. The inversion method uses smoothing and damping to regularize the solution; due to the significantly increased number of model parameters relative to the isotropic case, we performed a careful analysis for parameter selection to determine whether “leakage” occurs between isotropic and anisotropic model parameters. We observe a robust pattern of anisotropic fast directions in the mid‐crust that are consistent with large‐scale tectonic trends based on magnetic‐anomaly patterns. In particular, a distinctive double‐indentor shape for the Superior craton is clearly expressed in both data sets. This pattern breaks down deeper in the crust, suggesting that some degree of lithospheric decoupling in the lower crust, such as channel flow, occurred during orogenesis. Given regional evidence for vertically coherent deformation in the crust and underlying mantle, we interpret this pattern in the lower crust as a tectonic overprint that post‐dates the main phase of Trans‐Hudson deformation. At most levels in the crust, we observe a profound change in direction of anisotropic fast direction across an inferred suture beneath Hudson Bay.

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Section: Tectonic Settingmentioning

confidence: 99%

Crustal anisotropy beneath Hudson Bay from ambient noise tomography: Evidence for post‐orogenic lower‐crustal flow?

Pawlak¹,

Eaton²,

Darbyshire³

et al. 2012

J. Geophys. Res.

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“…These pervasive, gently dipping ductile fabrics represent one plausible explanation for the characteristically high reflectivity and lamellae observed in the lower crustal portions of many deep seismic reflection profiles [e.g., Meissner et al , 2006]. These dramatic reflection patterns have been documented across numerous collisional orogens, including: the Pyrenees, the Himalayas, and the Trans‐Hudson [ Hajnal et al , 2005; Hauck et al , 1998; Ross et al , 2004; Roure et al , 1989]. A fundamental issue in all of the above observations concerns the deformation mechanisms that attend lower crustal flow and the degree to which lower crust partitions strain [e.g., Williams and Jiang , 2005; Williams et al , 2006].…”

Section: Introductionmentioning

confidence: 99%

“…(a) Simplified geologic map of the western Canadian Shield compiled and modified after Hoffman [1988], Tella et al [2000], Ross [2002], and Hajnal et al [2005]. Note location of Figure 1b at center.…”

Section: Introductionmentioning

confidence: 99%

Subhorizontal fabric in exhumed continental lower crust and implications for lower crustal flow: Athabasca granulite terrane, western Canadian Shield

Dumond¹,

Gonçalves

Williams

et al. 2010

Tectonics

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The >20,000 km2 Athabasca granulite terrane is one of Earth's largest exposures of continental lower crust. The terrane is underlain by heterogeneous isobarically cooled orthogneisses termed the Mary batholith. A transect across the batholith documents early, penetrative subhorizontal to gently dipping gneissic foliation (S1). Kilometer‐ to meter‐scale domains of S1 contain lineations (L1) defined by ribbons of recrystallized K‐feldspar + plagioclase + quartz + amphibole ± orthopyroxene. L1 coincides with garnet aggregates, elongate mafic enclaves, and core‐and‐mantle structure in feldspar porphyroclasts. Lineations are coaxial with hinges of isoclinally folded layering (F1). L1 is interpreted as a composite mineral lineation with intersection and stretching components. Kinematics are uniformly top‐to‐the‐ESE. Thermobarometry derived from synkinematic phases is compatible with granulite‐grade (∼800°C) ductile lower crustal flow during D1 at ∼0.9 GPa (∼30 km paleodepths). Results from electron probe microanalyzer (EPMA) Th‐U‐total Pb monazite geochronology support Neoarchean (circa 2.60–2.55 Ga) garnet growth and melt‐enhanced flow. Metamorphic reactions accompanying D1 strain were synkinematic, with preferential nucleation of high‐Ca garnet and amphibole in the Na‐rich mantles of recrystallized plagioclase porphyroclasts. Relatively H2O‐poor and/or CO2‐rich conditions during D1 are required by the preservation of fine‐grained microstructures. Subhorizontal tectonites in the Mary batholith may represent an important field‐based analog for lower crustal flow during orogenesis or large magnitude extension. The results illustrate the evolving strength of continental lower crust. Neoarchean subhorizontal flow of weak lower crust was followed by near‐isobaric cooling and strengthening. Paleoproterozoic deformation events produced steep fabrics (S2), steeply dipping shear zones, and reactivation of S1, a record of strain localization and strain hardening in an isobarically cooled anisotropic medium.

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“…From crustal‐scale multichannel seismic reflection investigations, instances of anomalously bright midcrustal reflections in otherwise nonreflective crust have been imaged at a number of locations around the world. Because of the strength and character of the reflections and their overall geometries, several of these packages have been interpreted as resulting from dolerite sheets intruded into crystalline basement [e.g., Litak and Hauser , 1992; Mandler and Clowes , 1997; Papasikas and Juhlin , 1997; Ross and Eaton , 1997; Mandler and Clowes , 1998; Hajnal et al , 2005]. Seismically, these sequences are generally characterized by horizontal to subhorizontal discrete bands of bright coherent reflections that extend for tens to hundreds of kilometers and are confined within the mid to upper crust.…”

Section: Occurrence Of Midcrustal Igneous Sheet Intrusionsmentioning

confidence: 99%

Possible role of midcrustal igneous sheet intrusions in cratonic arch formation

2007

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Factors controlling widespread cratonic arch formation across western North America from the Early Paleozoic to the Middle Mesozoic remain poorly understood. While a number of causes, such as mantle hot spots, lithospheric contraction, mantle flow, and lithospheric flexure due to surface loading, have been suggested to explain the localized uplift of basement blocks on otherwise tectonically quiescent margins, a variety of mechanisms may be at work. Here, we test the hypothesis that seismically detected packages of discrete midcrustal igneous sheet intrusions impart rheological contrasts within the crust, which act as seeds for cratonic arch formation in the presence of weak intraplate compression, using finite element modeling of intraplate deformation. We find that the seismically resolved sills can generate significant surface uplift in the presence of modest strain rates over reasonable orogenic timescales. Cratonic arch formation would be enhanced in the presence of additional thin, seismically unresolvable sills. While midcrustal sheet intrusions may be just one of many factors influencing cratonic arch formation, their presence in northern Alberta, Canada, can help explain the asymmetric configuration of the well‐studied Peace River Arch.

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The Sask Craton and Hearne Province margin: seismic reflection studies in the western Trans-Hudson Orogen

Cited by 56 publications

References 29 publications

Crustal anisotropy beneath Hudson Bay from ambient noise tomography: Evidence for post‐orogenic lower‐crustal flow?

Crustal anisotropy beneath Hudson Bay from ambient noise tomography: Evidence for post‐orogenic lower‐crustal flow?

Subhorizontal fabric in exhumed continental lower crust and implications for lower crustal flow: Athabasca granulite terrane, western Canadian Shield

Possible role of midcrustal igneous sheet intrusions in cratonic arch formation

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