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Opatica Subprovince

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Journal Article

SOKOLOVAITE AND EVOLVED LITHIAN MICAS FROM THE EASTERN MOBLAN GRANITIC PEGMATITE, OPATICA SUBPROVINCE, QUEBEC, CANADA Available to Purchase

Eric G. Potter, Richard P. Taylor, Peter C. Jones, André E. Lalonde, Gary H.K. Pearse, Ralph Rowe
Published: 01 April 2009
The Canadian Mineralogist (2009) 47 (2): 337–349.
DOI: https://doi.org/10.3749/canmin.47.2.337
...–Evans greenstone belt of the Opatica Subprovince in Quebec. The main pegmatite body of the Eastern block comprises a near-vertical dyke that is simply zoned, with an aplitic border surrounding an extensive zone of quartz–spodumene pegmatite. Within this extensive unit, irregular quartz- and lepidolite...
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View PDF for article title, SOKOLOVAITE AND EVOLVED LITHIAN MICAS FROM THE EASTERN MOBLAN GRANITIC PEGMATITE, <span class="search-highlight">OPATICA</span> <span class="search-highlight">SUBPROVINCE</span>, QUEBEC, CANADA
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Journal Article

Orogen parallel and transverse shearing in the Opatica belt, Quebec: implications for the structure of the Abitibi Subprovince Free

Keith Benn, Edward W. Sawyer, Jean-Luc Bouchez
Published: 01 November 1992
Canadian Journal of Earth Sciences (1992) 29 (11): 2429–2444.
DOI: https://doi.org/10.1139/e92-191
...Keith Benn; Edward W. Sawyer; Jean-Luc Bouchez Abstract The late Archean Opatica granitoid-gneiss belt is situated within the northern Abitibi Subprovince, along the northern margin of the Abitibi greenstone belt. Approximately 200 km of structural section was mapped along three traverses within...
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Journal Article

Structural evolution and U-Pb geochronology of the metasedimentary Nemiscau subprovince, Canada: implications for Archean tectonics in the Superior Province Available to Purchase

Rocío Pedreira Pérez, Alain Tremblay, Yannick Daoudene, Jean David, Daniel Bandyayera
Published: 27 September 2022
Canadian Journal of Earth Sciences (2023) 60 (7): 865–896.
DOI: https://doi.org/10.1139/cjes-2022-0054
... and Opatica subprovinces. The Nemiscau consists of variably migmatized metasedimentary rocks and felsic to intermediate gneisses and plutonic suites. Mafic-to-ultramafic metavolcanic rocks occur along its northern and southern boundaries. Previous structural and metamorphic studies suggested...
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View PDF for article title, Structural evolution and U-Pb geochronology of the metasedimentary Nemiscau <span class="search-highlight">subprovince</span>, Canada: implications for Archean tectonics in the Superior Province
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Journal Article

Crustal models of the eastern Superior Province, Quebec, derived from new gravity data Available to Purchase

Hamid Telmat, Jean-Claude Mareschal, Clément Gariépy, Jean David, Caroline N. Antonuk
Published: 02 April 2000
Canadian Journal of Earth Sciences (2000) 37 (2-3): 385–397.
DOI: https://doi.org/10.1139/e99-080
... transect along the ∼260 km long Lithoprobe seismic line 48, across the northern Abitibi and Opatica subprovinces. For the Abitibi–Opatica segment, the interpretation is consistent with the Lithoprobe seismic profile. It calls for crustal thickening near the boundary between the Abitibi and Opatica belts...
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View PDF for article title, Crustal models of the eastern Superior Province, Quebec, derived from new gravity data
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Journal Article

Structural analysis and metamorphism of the Barlow Fault Zone, Chibougamau area, Neoarchean Abitibi Subprovince: implications for gold mineralization Available to Purchase

Pierre Bedeaux, Antoine Brochu, Lucie Mathieu, Damien Gaboury, Réal Daigneault
Published: 05 November 2020
Canadian Journal of Earth Sciences (2021) 58 (6): 554–571.
DOI: https://doi.org/10.1139/cjes-2020-0048
... of the Abitibi Subprovince, an Apogee Metal Earth seismic reflection survey identified an association between an exceptional shallow-dipping subsurface reflector zone and the Barlow Fault Zone visible at the surface. This fault zone is located adjacent to the Opatica Subprovince and shares many characteristics...
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View PDF for article title, Structural analysis and metamorphism of the Barlow Fault Zone, Chibougamau area, Neoarchean Abitibi <span class="search-highlight">Subprovince</span>: implications for gold mineralization
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Journal Article

Crustal geometry of the Abitibi Subprovince, in light of three-dimensional seismic reflector orientations Free

G Bellefleur, A J Calvert, M C Chouteau
Published: 01 May 1998
Canadian Journal of Earth Sciences (1998) 35 (5): 569–582.
DOI: https://doi.org/10.1139/e97-129
..., subparallel, dipping at an average of 30° toward the north. These north-dipping reflectors are partly disrupted by a low-reflectivity zone, which is attributed to rocks of the Opatica Subprovince, located underneath the northern Abitibi belt. Lower-crustal reflectors have a similar, shallowly north-dipping...
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Journal Article

Heat flow and deep thermal structure near the southeastern edge of the Canadian Shield Available to Purchase

J.C. Mareschal, C. Jaupart, C. Gariépy, L.Z. Cheng, L. Guillou-Frottier, G. Bienfait, R. Lapointe
Published: 02 April 2000
Canadian Journal of Earth Sciences (2000) 37 (2-3): 399–414.
DOI: https://doi.org/10.1139/e98-106
... of borehole conductivity, we have rated its reliability as B. This site lies within the Frotet-Evans greenstone belt in the Opatica subprovince ( Simard 1987 ; Sawyer and Benn 1993 ). Two boreholes, drilled in 1990, were logged in 1995. These boreholes intersect the typical mafic volcanic sequences...
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View PDF for article title, Heat flow and deep thermal structure near the southeastern edge of the Canadian Shield
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Journal Article

Delineating mineralization and imaging the regional structure with magnetotellurics in the region of Chibougamau (Canada) Available to Purchase

Michel Chouteau, Ping Zhang, Denis J. Dion, Bernard Giroux, Rémy Morin, Stefka Krivochieva
Journal: Geophysics
Published: 01 May 1997
Geophysics (1997) 62 (3): 730–748.
DOI: https://doi.org/10.1190/1.1444183
... a far more complex conductivity structure than anticipated. The sheet-like shallow conductor lies near the boundary between the conductive southern section located in the Abitibi subprovince and the resistive northern section located in the Opatica subprovince. It extends to a depth of 250 m. Two other...
View PDF for article title, Delineating mineralization and imaging the regional structure with magnetotellurics in the region of Chibougamau (Canada)
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Book Chapter

Continents never forget: seismological record of lithospheric deformation 1 billion years ago Available to Purchase

Author(s)
Andrew Hynes, Huaiyu Yuan, Vadim Levin
Book: The Consummate Geoscientist: A Celebration of the Career of Maarten de Wit
Series: Geological Society, London, Special Publications
Publisher: Geological Society of London
Published: 04 October 2023
DOI: 10.1144/SP531-2022-164
EISBN: 9781786209634
... Abstract A seismic array extended from the Grenville Province into the Abitibi and Opatica subprovinces of the Superior Province, Canada. We use P-to-S converted waves in seismograms of distant earthquakes to probe boundaries in seismic properties, and demonstrate the presence of a prominent...
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Abstract
View PDF for content titled, Continents never forget: seismological record of lithospheric deformation 1 billion years ago
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Abstract A seismic array extended from the Grenville Province into the Abitibi and Opatica subprovinces of the Superior Province, Canada. We use P-to-S converted waves in seismograms of distant earthquakes to probe boundaries in seismic properties, and demonstrate the presence of a prominent seismic feature that dips NNW into the mantle beneath the Grenville Front. We use two variants of receiver function (RF) analysis, a common conversion-point (CCP) imaging that combines seismic signals from multiple paths connecting sources and receivers, and harmonic decomposition of RF data that separates signals according to their direction in the cone of paths from which the signals have come. CCP images show the crust beneath the Grenville Province to be thicker than beneath the Superior Province, and identify a NNW-dipping boundary beneath the Grenville Front. Harmonic RF analysis shows that this feature is associated with seismic anisotropy in upper-mantle peridotite, and that this anisotropic feature extends to depths of at least 70 km. We interpret the feature as the result of a NNW-dipping shear zone formed within the mantle lithosphere during the Grenvillian continental collision. It could have accommodated internal deformation within Laurentian lithosphere or, more speculatively, mark the contact with the impacting Amazonian lithosphere.

Journal Article

Nd and Pb isotopes from the Lake of the Woods greenstone belt, northwestern Ontario: implications for mantle evolution and the formation of crust in the southern Superior Province Available to Purchase

John A. Ayer, Jaroslav Dostal
Published: 10 November 2000
Canadian Journal of Earth Sciences (2000) 37 (12): 1677–1689.
DOI: https://doi.org/10.1139/e00-067
... of rocks derived from old crustal terrains, such as the Winnipeg River and Opatica subprovinces. This type of isotopic heterogeneity could be the result of crustal contamination or derivation from metasomatized mantle. Contamination of the mantle wedge by influx of fluids derived from partial melting...
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View PDF for article title, Nd and Pb isotopes from the Lake of the Woods greenstone belt, northwestern Ontario: implications for mantle evolution and the formation of crust in the southern Superior Province
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Image
Geological map of the Nemiscau, La Grande, and Opatica subprovinces in the study area. Foliation trajectories from field data (MERN, this study) and aeromagnetic images (Fig. 2; DʼAmours 2011; DʼAmours and Intissar 2012). Abbreviations: ASZ, Albanel shear zone; CaSZ, Cabot shear zone; CoSZ, Colomb shear zone; ESZ, Échancrure shear zone; NaSZ, Naquiperdu shear zone; NeSZ, Nemiscau shear zone; NiSZ, Nisk shear zone; NoSZ, Nottaway shear zone; RSZ, Rupert shear zone. U-Pb geochronology sample locations are indicated (numbered white squares; Zr, zircon; Mnz, monazite): 1. 15-RP-6001-A1 (Zr); 2. 15-RP-6036-A1 (Zr); 3. 15-DB-1075-A1 (Zr); 4. 16-RP-6035-B1 (Zr); 5. 16-DB-1081-A1 (Zr); 6. 16-DB-1081-B1 (Zr); 7. 17-RP-6504-A1 (Zr); 8. 17-RP-6504-C1 (Zr); 9. 16-RP-6178-A1 (Zr, Mnz); 10. 17-RP-6506-A1 (Zr); 11. 17-RP-6506-B1 (Zr); 12. 16-YD-2050-A2 (Zr); 13. 17-YD-2061-A2 (Zr); 14. 18-RP-6109-A1 (Mnz). Adapted from Bandyayera and Daoudene (2017, 2018a, 2018b), Bandyayera and Caron-Côté (2019). Modified from Pedreira Pérez et al. (2020).

Geological map of the Nemiscau, La Grande, and Opatica subprovinces in the ... Available to Purchase

Published: 27 September 2022
Fig. 1. Geological map of the Nemiscau, La Grande, and Opatica subprovinces in the study area. Foliation trajectories from field data (MERN, this study) and aeromagnetic images ( Fig. 2 ; DʼAmours 2011 ; DʼAmours and Intissar 2012 ). Abbreviations: ASZ, Albanel shear zone; CaSZ, Cabot shear
Image
Schematic model proposed for the tectonic and metamorphic evolution of the Nemiscau subprovince and adjacent La Grande and Opatica subprovinces between ca. 2725 and 2625 Ma. (A) ca. 2725–2705 Ma: pre-D2 deformation. Sinking of the sedimentary cover into a subsiding structural basin fed by the uplift and coeval denudation of the La Grande and Opatica subprovinces; (B) ca. 2695–2670 Ma: syn- to late-D2 deformation illustrating the onset of extensive migmatization up to amphibolite (AMP) and granulite (GRA) facies metamorphism of the supracrustal and TTG domains of the Nemiscau. The late exhumation of the innermost part of the Nemiscau basin is believed to have been accommodated by dip-slip D2 shear zones; (C) ca. 2655–2625 Ma: D3 deformation and coeval emplacement of syn-tectonic granitoids along reactivated D2 shears. See text for discussion.

Schematic model proposed for the tectonic and metamorphic evolution of the ... Available to Purchase

Published: 27 September 2022
Fig. 14. Schematic model proposed for the tectonic and metamorphic evolution of the Nemiscau subprovince and adjacent La Grande and Opatica subprovinces between ca . 2725 and 2625 Ma. (A) ca . 2725–2705 Ma: pre-D 2 deformation. Sinking of the sedimentary cover into a subsiding structural basin
Image
Wetherill concordia diagrams of zircon U-Pb analysis (HR-LA-ICP-MS) for plutonism and deformation events of the La Grande (A, C), Opatica (B), and Nemiscau (D, E) subprovinces. The number of analyses (n) within a 10% discordance threshold are indicated with the total number of analyses. Error ellipses represent 2σ uncertainty. Zircons extracted from each sample display several clustered populations distinguished by 207 Pb/206 Pb ages and SEM-CL images. Unclustered concordant analyses are not shown. LG, La Grande subprovince; N, Nemiscau subprovince; O, Opatica subprovince.

Wetherill concordia diagrams of zircon U-Pb analysis (HR-LA-ICP-MS) for plu... Available to Purchase

Published: 27 September 2022
Fig. 11. Wetherill concordia diagrams of zircon U-Pb analysis (HR-LA-ICP-MS) for plutonism and deformation events of the La Grande (A, C), Opatica (B), and Nemiscau (D, E) subprovinces. The number of analyses ( n ) within a 10% discordance threshold are indicated with the total number of analyses
Image
Wetherill concordia diagrams of zircon U-Pb analyses (HR-LA-ICP-MS) for orthogneisses and TTG's samples of the Opatica (9A, B) and Nemiscau (9C, D, E) subprovinces. The number of analyses (n) within a 10% discordance threshold are indicated with the total number of analyses. Error ellipses represent 2σ uncertainty. Zircons extracted from each sample display several clustered populations distinguished by 207Pb/206Pb ages and SEM-CL images. Unclustered concordant analyses are not shown. N, Nemiscau subprovince; O, Opatica subprovince.

Wetherill concordia diagrams of zircon U-Pb analyses (HR-LA-ICP-MS) for ort... Available to Purchase

Published: 27 September 2022
Fig. 9. Wetherill concordia diagrams of zircon U-Pb analyses (HR-LA-ICP-MS) for orthogneisses and TTG's samples of the Opatica (9A, B) and Nemiscau (9C, D, E) subprovinces. The number of analyses ( n ) within a 10% discordance threshold are indicated with the total number of analyses. Error
Image
(a) Comparison between observed and calculated gravity along the Nemiscau–La Grande transect. (b) Nemiscau–La Grande crustal density model. Op, Opatica subprovince.

( a ) Comparison between observed and calculated gravity along the Nemiscau... Available to Purchase

Published: 02 April 2000
Fig. 8. ( a ) Comparison between observed and calculated gravity along the Nemiscau–La Grande transect. ( b ) Nemiscau–La Grande crustal density model. Op, Opatica subprovince.
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Summary diagram displaying the main chronological constraints available for tectonometamorphic events described in the text. Data are from multiple sources, including this study (Beland 2011; Bynoe 2014; Daoudene et al. 2022; David 2018a, 2018b, 2020a, 2020b, 2021; Davis et al. 1994, 1995; Moukhsil et al. 2003). Nem, Nemiscau subprovince; Op, Opatica subprovince.

Summary diagram displaying the main chronological constraints available for... Available to Purchase

Published: 27 September 2022
; Davis et al. 1994 , 1995 ; Moukhsil et al. 2003 ). Nem, Nemiscau subprovince; Op, Opatica subprovince.
Image
View to the southeast across the 3-D metamorphic surface map for the Abitibi and adjacent Pontiac, Quetico, and Opatica subprovinces. Past and present orogenic gold producers are draped across the surface. They cluster along the slope of a north-facing metamorphic front that extends from the Val d’Or camp to 30 km west of Timmins camp.

View to the southeast across the 3-D metamorphic surface map for the Abitib... Available to Purchase

Published: 01 April 2007
FIGURE 5. View to the southeast across the 3-D metamorphic surface map for the Abitibi and adjacent Pontiac, Quetico, and Opatica subprovinces. Past and present orogenic gold producers are draped across the surface. They cluster along the slope of a north-facing metamorphic front that extends
Image

Fig. 13. Combined seismic-reflection profiles (lines 28 and 48; locations... Available to Purchase

Published: 16 April 2010
Fig. 13. Combined seismic-reflection profiles (lines 28 and 48; locations in Fig. 11 ) across the Abitibi–Opatica subprovinces of the eastern Superior Province (modified from Van der Velden 2007 ; see also Calvert et al. 1995 ). Note the prominent reflection Moho and the projection
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A 207Pb/204Pb vs. 206Pb/204Pb diagram showing the secondary isochron for feldspar separates from the Falcon Island pluton. Leached feldspars data from various samples as indicated in Table 2. A single stage isochron for evolution from 4.55 to 2.70 Ga with Canyon Diablo meteorite compositions (Tatsumoto et al. 1973) with μ1 values is also shown, as is the Stacey and Kramer (1975) crustal evolution curve (S–K). Fields of initial 207Pb/204Pb vs. 206Pb/204Pb for various suites from the southern Superior Province after Carignan et al. (1995) are (1) depleted mantle as represented by mafic to ultramafic flows and intrusions; (2) calc-alkaline trondhjemite–tonalite–granodiorite suites from the Abitibi subprovince; (3) alkaline and LREE-enriched plutons in the Abitibi, Wabigoon, and Wawa subprovinces; (4) gneisses and granitic plutons from the Pontiac, Abitibi, and Opatica subprovinces; (5) gneiss and granitic plutons from the Winnipeg River subprovince. The star represents the initial Pb composition of the Falcon Island pluton.

A 207 Pb/ 204 Pb vs. 206 Pb/ 204 Pb diagram showing the secondary isochro... Available to Purchase

Published: 10 November 2000
as represented by mafic to ultramafic flows and intrusions; (2) calc-alkaline trondhjemite–tonalite–granodiorite suites from the Abitibi subprovince; (3) alkaline and LREE-enriched plutons in the Abitibi, Wabigoon, and Wawa subprovinces; (4) gneisses and granitic plutons from the Pontiac, Abitibi, and Opatica
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Equal-area lower-hemisphere stereographic projections of structural data from the study area. Structural domains are separated by white lines. Planar structures (poles to foliation) in the gneissic and plutonic rocks of the La Grande and Opatica subprovinces correspond to composite S1-3 (S1 to S3), whereas linear structures correspond to a composite L2-3 lineation. Planar and linear structures in the Colomb-Chaboullié greenstone belt show composite S1-2 and L2 fabrics, respectively. Supracrustal domains of the Nemiscau (including Nemiscau and NE Nemiscau) and La Grande (Lac des Montagnes supracrustal belt) subprovinces show composite S2-3 planar fabrics, different L2 and L3 lineations, and composite F2-3 hinge folds. Planar and linear fabrics of the Nottaway shear zone correspond to S4 and L4, respectively. Data were compiled from SIGÉOM (sigeom.mines.gouv.qc.ca) and structural data acquired during this study.

Equal-area lower-hemisphere stereographic projections of structural data fr... Available to Purchase

Published: 27 September 2022
Fig. 5. Equal-area lower-hemisphere stereographic projections of structural data from the study area. Structural domains are separated by white lines. Planar structures (poles to foliation) in the gneissic and plutonic rocks of the La Grande and Opatica subprovinces correspond to composite S 1-3