乌拉尔铬铁矿(上):铬铁矿矿物化学及大地构造背景概述

IF 1.2 4区地球科学 Q2 GEOLOGY

Ofioliti Pub Date : 2012-06-30 DOI:10.4454/OFIOLITI.V37I1.404

G. Garuti, Evgeny V. Evgeny, O. Thalhammer, F. Zaccarini

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引用次数: 32

摘要

综述了乌拉尔地区14个超镁铁络合物中333个铬铁矿样品中已发表和未发表的铬铁矿组成。铬铁矿产于蛇绿岩杂岩的地幔单元和/或超莫霍堆积层序中，也产于阿拉斯加型侵入体中。从与蛇绿岩有关的巨型矿床(如Kempirsai、Ray-Iz、Voykar-Syninsky)到阿拉斯加型杂岩的亚经济矿化(如Svetly Bor、Kachkanar)，它们的规模各不相同。地幔铬铁矿以不协调的足状高铬矿体和亚协调的高铝铬铁矿细长透镜体的形式存在。在蛇绿岩的超莫霍层序中，铬铁矿主要为高铝品种，与橄榄岩和辉石岩堆积物交替呈和谐层状。在乌拉尔山脉的阿拉斯加型侵入岩中，铬铁矿以厘米至米大小的荚状和透镜状出现，与寄主灰铁矿具有同生或表观遗传关系。计算熔体成分与铬铁矿和比较均衡的铬铁矿成分与各种火山套房,和铬铁岩不同的深成复合物,使部门的乌拉尔铬铁岩分为四个不同的成分群,形成对应于不同地球动力学的环境:1)high-Al低钛套件(Al 2 O 3 > 20 wt %, Cr # 20 wt %, Cr # 0.70, 0.70 Al 2 O 3, Al 2 O 3 < 20 wt %, TiO 2 = 0.38 - -1.30 wt %,铁3 + # = 0.20 - -1.29,δ logf(o2) = +0.9 ÷ +5.9)代表了乌拉尔-阿拉斯加型侵入岩和东-哈巴内杂岩的铬铁矿。它们是在远高于FMQ缓冲层的氧逸度条件下由富铁岩浆(即FeO/MgO = 1.35)结晶而成的。该熔体具有高钛、高钾、钙碱性组成，与安卡拉石具有许多共同的地球化学特征。它是在俯冲弧环境下由流体交代地幔源部分熔融形成的。然而，与俄罗斯-远东克拉通的带状杂岩的相似性表明，阿拉斯加型熔体的形成可能并不局限于SSZ，岛弧环境。

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CHROMITITES OF THE URALS (PART 1): OVERVIEWOF CHROMITE MINERAL CHEMISTRY AND GEO-TECTONIC SETTING

Published and unpublished compositions of chromite in 333 chromitite samples from 14 ultramafic complexes of the Urals are overviewed. The chromitites occur in the mantle unit and/or the supra-Moho cumulate sequence of ophiolite complexes, as well as in Alaskan-type intrusions. They vary in size from giant ore deposits associated with ophiolites (e.g., Kempirsai, Ray-Iz, Voykar-Syninsky) to sub-economic mineralization in the Alaskan-type complexes (e.g., Svetly Bor, Kachkanar). Mantle-hosted chromitites occur either as discordant, podiform, high-Cr ore bodies and sub-concordant elongated lenses of high-Al chromite. In the supra-Moho sequences of ophiolites, chromitite is mainly of the high-Al variety, and occurs as concordant layers alternated with peridotite and pyroxenite cumulates. In the Alaskan-type intrusions of the Urals, chromitite occurs as centimeter to meter-size pods and lenses having syngenetic or epigenetic relationship with the host dunite. Calculated melt compositions in equilibrium with chromite and comparison of chromite composition with those from various volcanic suites, and chromitites from different plutonic complexes, allow division of the Urals chromitites into four different compositional groups, corresponding to different geodynamic environments of formation: 1) The high-Al, low-Ti suite (Al 2 O 3 > 20 wt%, Cr# 20 wt%, Cr# 0.70, Al 2 O 3 0.70, Al 2 O 3 < 20 wt%, TiO 2 = 0.38-1.30 wt%, Fe 3+ # = 0.20-1.29, δ logf(O 2 ) = +0.9 ÷ +5.9) is represented by chromitites from the Urals Alaskan-type intrusions and the East-Khabarny complex. They have crystallized from Fe-rich magma (av. FeO/MgO = 1.35) under oxygen- fugacity conditions well above the FMQ buffer. The melt is characterized by high-Ti, high-K, calc-alkaline composition, having many geochemical characteristics in common with ankaramites. It was generated by partial melting of a fluid-metasomatized mantle source, in a subduction-influenced arc setting. However, the close similarity with the zoned complexes emplaced in the Russian-Far-East craton suggests that formation of Alaskan-type melts may be not restricted to SSZ, island arc settings.

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来源期刊

Ofioliti 地学-地质学

CiteScore

2.40

自引率

7.70%

发文量

期刊介绍： Since 1976, Ofioliti provides an international forum for original contributions and reviews in the field of the geodynamics, petrology, geochemistry, biostratigraphy, stratigraphy, tectonics and paleogeography applied to ophiolitic terrains and modern oceanic lithosphere, including their sedimentary cover. Studies of topics such as geodynamics of the mantle, the evolution of orogens including ophiolites and paleoceanography are also welcome