Geological, petrologic, geochemical, and isotopic geochronological evidence for Grenville events at the western margin of the Siberian Craton are considered. These events were related to assembly of the Rodinia supercontinent. Multiple manifestations of riftogenic and within plate magmatism at the final stage of orogenic evolution gave rise to breakdown of Rodinia and the formation of the Paleoasian ocean. The results allowed us to develop a new concept on the Precambrian geological evolution of the Yenisei Ridge and the processes that created its tectonic structure. The chronological sequence of events in the history of the Transangarian Yenisei Ridge is based on geological evidence and isotopic dating of Precambrian complexes variable in geodynamic nature. Four tectonic stages dated at 1.4-1.1, 1.1-0.9, 0.90-0.85, and 0.8-0.6 Ga were controlled by collision and extension recognized from large regional linear crustal structural elements. The evolution of the Transangarian Yenisei Ridge, which lasted for ~650 Ma, corresponds in duration to supercontinental cycles that begin from rifting and breakdown of the predated supercontinent and was com pleted by orogeny and the formation of a new supercontinent. The regional geodynamic history correlates with the synchronous sequence and similar style of tectonothermal events at the periphery of the large Pre cambrian Laurentia and Baltica cratons. This is evidenced by paleocontinental reconstructions, which con firm close spatiotemporal links of Siberia with cratons in the northern Atlantic 1400-600 Ma ago and indi cate incorporation of the Siberian Craton into the ancient Nuna and Rodinia supercontinents.
Geological, petrological, geochemical, and isotope data from the Yenisei Ridge indicate three stages of rifting and attendant within-plate magmatism at 750, 700, and 670 Ma. The igneous rocks of the three stages are, respectively, metarhyolite-basalt, trachybasalt-trachyte, and alkali ultramafic (alkali picrite) associations. Magmatism was concurrent with terrigenous deposition of the Neoproterozoic Upper Vorogovka, Chingasan, and Chapa Groups. The volcanosedimentary complexes were deposited in narrow rift-like graben along faults. The earlier consolidated flanking uplifts of the graben experienced granitoid magmatism synchronously with rifting and within-plate volcanism. The respective plutonic events produced granitoid intrusions of the Ayakhta (760–750 Ma), Kutukas (690–700 Ma), and Middle Tatarka (~700 Ma) alkaline complexes, and the later (about 650–670 Ma) alkali ultramafic Chapa complex of carbonatites and metasomatites. Basalts and alkaline rocks are chemically similar to ocean-island and continental-rift basalts which have been reliably attributed to mantle plumes. Neoproterozoic rifting and within-plate magmatism were possibly related to the plume activity responsible for the breakup of Rodinia. These events in the Yenisei Ridge appear to be coeval with rifting and within-plate magmatic processes in other continental blocks which may have been parts of the Rodinia supercontinent.
The Onot and Bulun terranes are confined to the Sharyzhalgai Uplift in the southwestern margin of the Siberian craton. They consist of alternating blocks and nappes of Paleoarchean tonalite-trondhjemite-granodiorite complex and supracrustal metasedimentary-volcanogenic rocks of greenstone belts (GSB). The lower part of the Onot GSB is made up of a bimodal association of aporhyolite microgneisses with subordinate amphibolites, while the upper part consists of amphibolites associated with banded iron formation, metapelites, dolomitic marbles, and magnesites. The Urik GSB in the Bulun block comprises three rock associations:(1) garnet amphibolites and amphibolites alternating with kyanite-bearing mica schists and quartzite schists;(2) garnet-bearing biotite and amphibole crystalline schists with tectonic lenses of garnet amphibolites;(3) biotite and amphibole-biotite orthogneisses and biotite plagiogneisses. The microgneisses (metarhyolitoids) of the Onot belt are correlated with within-plate volcanic rocks and A-type granites. The composition of the amphibolites corresponds to high-Mg low-Ti tholeiitic basalts. The formation of metavolcanic rocks of the Onot GSB was related to the rifting of the Paleoarchean continental crust, which is supported by the formation of felsic metavolcanic rocks from an ancient tonalite source and by the geochemical signatures of crustal contamination of metabasalts. The amphibolites of the Urik GSB are subdivided into three petrogeochemical types. The first and second types correspond to high-and low-Mg tholeiitic basalts and have practically flat multielement patterns. The amphibolites of the third type correspond to subalkaline leucobasalts. Two types of orthogneisses are comparable with intermediate-acid volcanic rocks of the andesite-dacite and adakite series. In terms of geochemistry, the metamafic volcanic rocks of the Urik GSB represent the rocks of the oceanic crust. Oceanic settings of their formation are confirmed by an association of metavolcanic rocks with abyssal distal siliceous-argillaceous deposits. The formation of two types of intermediate-acid metavolcanic rocks of andesite-dacite and adakite associations, as well as garnet-bearing paraschists, was presumably related to subduction settings.
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