南乌拉尔吸积-碰撞体系泥盆纪-石炭系岩浆作用与成矿作用

IF 0.8 Q4 GEOCHEMISTRY & GEOPHYSICS

Geodynamics & Tectonophysics Pub Date : 2021-06-23 DOI:10.5800/gt-2021-12-2-0529

A. Kosarev, A. Vladimirov, A. Khanchuk, D. Salikhov, V. Kholodnov, T. Osipova, G. A. Kallistov, I. Seravkin, I. Rakhimov, G. T. Shafigullina

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引用次数: 1

摘要

南乌拉尔历史上的海洋阶段完成于奥陶世-早志留世。该地区奥陶系至泥盆纪事件包括中奥陶世至志留纪在东乌拉尔地区形成岛弧;晚志留世—早泥盆世俯冲带的西移与乌拉尔断裂及乌拉尔陶隆起海沟的形成;泥盆纪马格尼托格尔斯克岛弧体系的火山喷发和侵入。中晚古生代乌拉尔山系和阿尔泰山系的地球动力学演化是陆海过渡时期俯冲和碰撞环境的连续交替。马格尼托格尔斯克主要带的大部分火山活动与俯冲有关，并与鲁德尼阿尔泰早-中泥盆世的成矿事件在年龄和模式上具有相关性。火山旋回开始时的板块内火山作用记录了早(D1e2)和中(D2ef2)泥盆纪板块断裂。晚emian火山旋回分别形成了Buribay和Upper Tanalyk杂岩和VMS矿化;喀喇玛利塔什复合体及其与之相当的艾菲梯晚期-吉夫梯早期，以及吉夫梯下部的乌卢陶组。晚泥盆世-早石炭世的板块断裂阻碍了马格尼托格尔斯克岛弧，支持软流圈底辟作用。晚泥盆世-早石炭世形成新的西倾俯冲带和亚历山德罗夫卡岛弧。早石炭世的碰撞和另一次阻碍俯冲事件导致了与碰撞后板块相对滑动相对应的转换边缘环境，产生了另一次板块撕裂。碰撞后岩浆活动表现为碱性辉长花岗岩侵入岩，并伴有丰富的钛磁铁矿成矿作用(C1)。中石炭世至二叠纪，转换断裂持续存在，此时欧亚大陆完成了整合。成矿事件包括铜镍榴辉石(C2-3)的形成，以及花岗岩中大规模的金、钼、钨矿床(P1-2)。

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DEVONIAN-CARBONIFEROUS MAGMATISM AND METALLOGENY IN THE SOUTH URAL ACCRETIONARY-COLLISIONAL SYSTEM

The oceanic stage in the history of the South Urals completed in the Ordovician – Early Silurian. The Ordovician through Devonian events in the region included the formation of an island arc in the East Ural zone from the Middle Ordovician to Silurian; westward motion of the subduction zone in the Late Silurian – Early Devonian and the origin of a trench along the Main Ural Fault and the Uraltau Uplift; volcanic eruptions and intrusions in the Magnitogorsk island arc system in the Devonian. The Middle-Late Paleozoic geodynamic evolution of uralides and altaides consisted in successive alternation of subduction and collisional settings at the continent-ocean transition. The greatest portion of volcanism in the major Magnitogorsk zone was associated with subduction and correlated in age and patterns of massive sulfide mineralization (VMS) with Early – Middle Devonian ore-forming events in Rudny Altai. Within-plate volcanism at the onset of volcanic cycles records the Early (D1e2) and Middle (D2ef2) Devonian slab break off. The volcanic cycles produced, respectively, the Buribay and Upper Tanalyk complexes with VMS mineralization in the Late Emsian; the Karamalytash complex and its age equivalents in the Late Eifelian – Early Givetian, as well as the lower Ulutau Formation in the Givetian. Slab break off in the Late Devonian – Early Carboniferous obstructed the Magnitogorsk island arc and supported asthenospheric diapirism. A new subduction zone dipping westward and the Aleksandrovka island arc formed in the Late Devonian – Early Carboniferous. The Early Carboniferous collision and another event of obstructed subduction led to a transform margin setting corresponding to postcollisional relative sliding of plates that produced another slab tear. Postcollisional magmatism appears as alkaline gabbro-granitic intrusives with related rich Ti-magnetite mineralization (C1). Transform faulting persisted in the Middle Carboniferous through Permian, when the continent of Eurasia completed its consolidation. The respective metallogenic events included formation of Cu-Ni picritic dolerites (C2–3), as well as large-scale gold and Mo-W deposits in granites (P1–2).

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来源期刊

Geodynamics & Tectonophysics GEOCHEMISTRY & GEOPHYSICS-

CiteScore

1.20

自引率

14.30%

发文量

审稿时长

24 weeks

期刊介绍： The purpose of the journal is facilitating awareness of the international scientific community of new data on geodynamics of continental lithosphere in a wide range of geolchronological data, as well as tectonophysics as an integral part of geodynamics, in which physico-mathematical and structural-geological concepts are applied to deal with topical problems of the evolution of structures and processes taking place simultaneously in the lithosphere. Complex geological and geophysical studies of the Earth tectonosphere have been significantly enhanced in the current decade across the world. As a result, a large number of publications are developed based on thorough analyses of paleo- and modern geodynamic processes with reference to results of properly substantiated physical experiments, field data and tectonophysical calculations. Comprehensive research of that type, followed by consolidation and generalization of research results and conclusions, conforms to the start-of-the-art of the Earth’s sciences.