Hudsonian tectonism in the western Churchill Province of Canada encompassed two periods of granit... more Hudsonian tectonism in the western Churchill Province of Canada encompassed two periods of granitic plutonism. The Hudson suite plutons represent xenocryst-rich, mainly monzogranitic, near-minimum melts emplaced near their source region in thickened middle crust; the Nueltin syenogranites and Pitz rhyolites were generated by intrusion of basalt into extending crust. Zircons from four Nueltin suite samples and 20 Hudson suite samples were analysed by U-Pb SHRIMP techniques. Intrusion of the Hudson suite lasted ca. 50 million years, from 1845 to 1795 Ma, with a peak around 1825 Ma, and the Nueltin suite from 1765 to 1750 Ma, following a ca. 30-million-year period of magmatic quiescence. A marked contrast in Th/U ratios was found in igneous zircon from Hudson suite samples south (Th/U = 0.066) and north (Th/U = 1.07) of the northern margin of the Central Hearne domain and is attributed to a difference in the nature of the melting process, with the lower values representing ultrametamorphism and the higher values representing bulk melting resulting from contact with mafic igneous magma. Whole-rock Nd isotopic measurements, with average ε 143 Nd near -10, indicate a dominant late Archean crustal component in both suites of granites, reflected by numerous inherited zircon ages between 2720 and 2650 Ma in Hudson granites. Further south, along the Manitoba border, inherited zircons of 3500-3000 Ma, together with previously published U-Pb data on gneisses and ca. 3 Ga T DM model ages of Hudson granites, indicate the presence of middle to early Archean crust.
Paleoproterozoic igneous rocks in the Archean hinterland of the Paleoproterozoic Trans-Hudson oro... more Paleoproterozoic igneous rocks in the Archean hinterland of the Paleoproterozoic Trans-Hudson orogen (THO) consist of voluminous late syn-orogenic to post-orogenic monzonite to granite (Hudson granitoids; ≈1850–1810 Ma), and contemporaneous ultrapotassic lamprophyre dykes and volcanic rocks (Dubawnt minettes) that are interbedded with alluvial fan and fluvial deposits (Baker Lake Group, lower Dubawnt Supergroup). They were followed at approximately 1750 Ma by rapakivi granite (Nueltin granite) and porphyritic rhyolite associated with aeolian sandstone (Pitz Formation, middle Dubawnt Supergroup). The tectonic cycle ended with the deposition of conglomerates and sandstones in a large sag basin (Thelon Formation, upper Dubawnt Supergroup, ≈1.72 Ga). The Hudson granitoids, which are strongly concentrated northwest of the THO, were broadly synchronous with terminal collision between the Archean Churchill and Superior cratons and the development of NE-trending ductile structures in the Western Churchill Province (WCP) that may be related to tectonic escape to the northeast. They were emplaced at mid-crustal level and no volcanic equivalents are preserved. Fault-bounded basins containing the minette volcanic rocks are located farther west in a domain dominated more by brittle faulting. The Nueltin granites, emplaced during a period of active extensional faulting, are present in a band extending southwest from the minette basins toward a preserved remnant of the sag basin (the Athabasca basin). Hudson granitoids are largely absent from this band but reappear west of it, indicating a higher crustal level of exposure in a downdropped Nueltin ‘corridor’. The Nd isotope composition of the three suites is similar (minettes: εNd,1830 Ma=−5 to −11; Hudson granitoids: εNd,1830 Ma=−7 to −13.5; Nueltin suite: εNd,1750 Ma=−7 to −10.5), and they have late Archean model ages that match those of average Archean WCP rocks. The Hudson granitoids are rich in inherited Archean zircon, and both granitoid suites are interpreted as crustal melts. Some Nueltin granites and Pitz rhyolites are mingled with basalt, and the Nueltin suite fits a commonly cited model for rapakivi granite production, which postulates injection of basalt into extending, brittly faulted crust. The Hudson granitoids are similar to late syn- to post-orogenic plutons in numerous other collisional hinterlands, which are typically associated with ultrapotassic lamprophyres. The minettes, which have high mg# and bear mantle xenocrysts, must have a mantle source component, and their source region could have been subduction-enriched lithospheric mantle. However, their source had only slightly lower time-integrated LREE enrichment than did that of the granitoids, and the incompatible element signatures of the two suites are strikingly similar. The minette source region may have been in a zone of mixed crust and upper mantle, formed during a shortening event which resulted in crustal thickening and subsequent melting at mid-crustal layers to form the Hudson granitoid plutons. The generation and emplacement of minette melts may have been promoted by extension related to a combination of slab breakoff, gravitational collapse of thickened crust, and strike-slip faulting in the deforming hinterland. Subsequent anorogenic rapakivi granite-basalt activity may have been triggered by lithospheric mantle delamination. The hinterland tectonic cycle of the WCP was repeated in other large Archean terranes that were deformed during the early Proterozoic, but the igneous and sedimentary record is unusually complete in the WCP.
Hudsonian tectonism in the western Churchill Province of Canada encompassed two periods of granit... more Hudsonian tectonism in the western Churchill Province of Canada encompassed two periods of granitic plutonism. The Hudson suite plutons represent xenocryst-rich, mainly monzogranitic, near-minimum melts emplaced near their source region in thickened middle crust; the Nueltin syenogranites and Pitz rhyolites were generated by intrusion of basalt into extending crust. Zircons from four Nueltin suite samples and 20 Hudson suite samples were analysed by U-Pb SHRIMP techniques. Intrusion of the Hudson suite lasted ca. 50 million years, from 1845 to 1795 Ma, with a peak around 1825 Ma, and the Nueltin suite from 1765 to 1750 Ma, following a ca. 30-million-year period of magmatic quiescence. A marked contrast in Th/U ratios was found in igneous zircon from Hudson suite samples south (Th/U = 0.066) and north (Th/U = 1.07) of the northern margin of the Central Hearne domain and is attributed to a difference in the nature of the melting process, with the lower values representing ultrametamorphism and the higher values representing bulk melting resulting from contact with mafic igneous magma. Whole-rock Nd isotopic measurements, with average ε 143 Nd near -10, indicate a dominant late Archean crustal component in both suites of granites, reflected by numerous inherited zircon ages between 2720 and 2650 Ma in Hudson granites. Further south, along the Manitoba border, inherited zircons of 3500-3000 Ma, together with previously published U-Pb data on gneisses and ca. 3 Ga T DM model ages of Hudson granites, indicate the presence of middle to early Archean crust.
Paleoproterozoic igneous rocks in the Archean hinterland of the Paleoproterozoic Trans-Hudson oro... more Paleoproterozoic igneous rocks in the Archean hinterland of the Paleoproterozoic Trans-Hudson orogen (THO) consist of voluminous late syn-orogenic to post-orogenic monzonite to granite (Hudson granitoids; ≈1850–1810 Ma), and contemporaneous ultrapotassic lamprophyre dykes and volcanic rocks (Dubawnt minettes) that are interbedded with alluvial fan and fluvial deposits (Baker Lake Group, lower Dubawnt Supergroup). They were followed at approximately 1750 Ma by rapakivi granite (Nueltin granite) and porphyritic rhyolite associated with aeolian sandstone (Pitz Formation, middle Dubawnt Supergroup). The tectonic cycle ended with the deposition of conglomerates and sandstones in a large sag basin (Thelon Formation, upper Dubawnt Supergroup, ≈1.72 Ga). The Hudson granitoids, which are strongly concentrated northwest of the THO, were broadly synchronous with terminal collision between the Archean Churchill and Superior cratons and the development of NE-trending ductile structures in the Western Churchill Province (WCP) that may be related to tectonic escape to the northeast. They were emplaced at mid-crustal level and no volcanic equivalents are preserved. Fault-bounded basins containing the minette volcanic rocks are located farther west in a domain dominated more by brittle faulting. The Nueltin granites, emplaced during a period of active extensional faulting, are present in a band extending southwest from the minette basins toward a preserved remnant of the sag basin (the Athabasca basin). Hudson granitoids are largely absent from this band but reappear west of it, indicating a higher crustal level of exposure in a downdropped Nueltin ‘corridor’. The Nd isotope composition of the three suites is similar (minettes: εNd,1830 Ma=−5 to −11; Hudson granitoids: εNd,1830 Ma=−7 to −13.5; Nueltin suite: εNd,1750 Ma=−7 to −10.5), and they have late Archean model ages that match those of average Archean WCP rocks. The Hudson granitoids are rich in inherited Archean zircon, and both granitoid suites are interpreted as crustal melts. Some Nueltin granites and Pitz rhyolites are mingled with basalt, and the Nueltin suite fits a commonly cited model for rapakivi granite production, which postulates injection of basalt into extending, brittly faulted crust. The Hudson granitoids are similar to late syn- to post-orogenic plutons in numerous other collisional hinterlands, which are typically associated with ultrapotassic lamprophyres. The minettes, which have high mg# and bear mantle xenocrysts, must have a mantle source component, and their source region could have been subduction-enriched lithospheric mantle. However, their source had only slightly lower time-integrated LREE enrichment than did that of the granitoids, and the incompatible element signatures of the two suites are strikingly similar. The minette source region may have been in a zone of mixed crust and upper mantle, formed during a shortening event which resulted in crustal thickening and subsequent melting at mid-crustal layers to form the Hudson granitoid plutons. The generation and emplacement of minette melts may have been promoted by extension related to a combination of slab breakoff, gravitational collapse of thickened crust, and strike-slip faulting in the deforming hinterland. Subsequent anorogenic rapakivi granite-basalt activity may have been triggered by lithospheric mantle delamination. The hinterland tectonic cycle of the WCP was repeated in other large Archean terranes that were deformed during the early Proterozoic, but the igneous and sedimentary record is unusually complete in the WCP.
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