大洋板块地层(OPS)简介及评述

大洋板块地层(Ocean Plate Stratigraphy)是由日本地质学家Isozaki在1990年首先提出来的,基本含义是大洋板块在从洋中脊到海沟俯冲带的运动过程中形成的一套构造-沉积地层。近年来,关于大洋板块地层的研究取得了长足的进展,丰富了大洋板块地层的内涵。本文着重介绍大洋板块地层的基本概念、物质组成、形成环境及构造特征。在此基础上,对大洋板块地层在区域地质矿产调查中的作用进行了讨论,建议在造山带地质研究中采用"俯冲增生杂岩"取代"大洋板块地层"。因为在成因上,地层并不等同于杂岩。     

Alteration of Platinum-Group and Base-Metal Mineral Assemblages in Ophiolite Chromitites from the Dobromirtsi Massif,Rhodope Mountains (Bulgaria)

The Dobromirtsi Ultramafic Massif, located in the Rhodope Mountains (SE Bulgaria), is a portion of a Paleozoic sub-oceanic mantle affected by polyphase regional metamorphism. This massif contains several small, podiform chromitite bodies which underwent the same metamorphic evolution as their host peridotites. Like other ophiolite chromitites, those found in Dobromirtsi carry abundant platinum-group minerals (PGM) and base-metal minerals (BMM). The PGM consist mainly of Ru-, Os-, and Ir-based PGM (laurite RuS₂-erlichmanite OsS₂, Os-Ru-Ir alloys, irarsite [IrAsS], Ru-rich pentlandite, and an unknown Ir-sulfide) but minor Rh- and Pd-based PGM (hollingworthite [RhAsS] and a series of unidentified stannides and sulfantimonides) are also present. In contrast, the BMM are dominated by pentlandite (Ni,Fe)₉S₈, followed by heazlewoodite (Ni₃S₂), breithauptite (NiSb), maucherite (Ni₁₁As₈), godlevskite (Ni₇S₆), gersdorffite (NiAsS), millerite (NiS), undetermined minerals containing Ni, As and Sb, orcelite (Ni_5-XAs₂), awaruite (Ni₃Fe) and chalcopyrite (CuFeS₂). The detailed study of the textural relationships, morphology and composition of the PGM and BMM inclusions indicate the existence of two different PGM-BMM assemblages: (i) a primary or magmatic; and (ii) a secondary related with postmagmatic alteration. The PGM and BMM inclusions in unaltered zones of chromite crystals (mainly laurite-erlichmanite and pentlandite) are considered to be primary magmatic minerals formed under variable temperature (1200–1100°C) and sulfur fugacity (between −2 and −0.5 log fS₂). In contrast, PGM and BMM located along altered edges of chromite and serpentinised silicate matrix are considered to be secondary, formed from or re-equilibrated with altering fluids. Secondary PGM and BMM assemblages are considered as result of the combination of reducing and oxidising events related with regional metamorphism. Under low fO₂ states, fS₂ also drops giving place to the formation of S-poor Ni-rich sulfides and secondary Ru-alloys by desulfurisation of primary S-containing minerals. In contrast, predominance of platinum-group elements and/or base-metal arsenides and sulfarsenides associated with the altered edges of chromite (chromite strongly enriched in Fe₂O₃) is related with the fixing of remobilised PGE (mainly Ir, Rh and Pd) and base-metals (mainly Ni and Fe) when late oxidising fluids supplied As as well as Sb and Sn.     

雅鲁矿：一种金属碳化物新矿物

雅鲁矿产于中国西藏曲松县罗布莎蛇绿岩铬铁矿山中(29°5′N, 92°5′E, 拉萨市东南约200公里处)。伴生矿物有金刚石、碳硅石、方铁矿、锇铱矿、铱锇矿(自然锇)、方镁石、铬铁矿等。与雅鲁矿伴生的金属碳化物有桐柏矿、陨碳铁矿、钛碳矿和曲松矿(IMA2007-034)。雅鲁矿及其伴生矿物都是从人工重砂大样中经选矿富集后得到的。该矿物为不规则粒状,粒径20~60 μm,钢灰色,不透明。莫氏硬度：5.5~6,性脆｛001｝解理完全,贝壳状断口。化学分子式为：(Cr4Fe4Ni)∑9C4, 或 (Cr, Fe, Ni)∑9C4。六方晶系,空间群：P63/mc, a=18.839(2), c=4.4960(9), V=745.7(2)3,Z=6,计算密度：7.19 g/cm3。雅鲁矿己被国际新矿物命名及矿物分类委员会(CNMMNC)批准为新矿物(IMA2007035),样品(M11650号)保存在中国地质博物馆     

西藏拉嘎蛇绿岩壳层熔岩的岩的岩石地球化学及成因

拉嘎蛇绿岩位于西藏雅鲁藏布板块缝合带中段。通过野外地质考察，首次对该蛇绿岩进行较系统的分析测试和综合对比研究，提出拉嘎蛇绿岩类似于非典型大洋中脊玄武岩（ＭＯＲＢ）的大陆边缘洋盆成因蛇绿岩，是新特提斯大洋岩石圈在俯冲消亡过程中的残片。     

The fragment of Paleo-Tethys ophiolite from central Qiangtang, Tibet:Geochemical evidence of meta-basites in Guoganjianian

N-MORB-type metabasites are discovered in the Guoganjianian area, central Qiangtang, Tibet, which are mainly metagabbro with cumulate structure and metabasalt. The rocks are distributed nearly from west to east unconformably underlying the Wanghuling Group of upper Triassic. On the basis of geo- chemical analysis, we find that the content of SiO2 is 43.03%―53.42%, and TiO2 1%―2.67%, Al2O3 16.75%―21.52%, CaO 7.03%―11.13%, K2O 0.05%―0.38%; the REE pattern is slight depletion or flat, and the trace spider diagram is like that of N-MORB, so we consider that the metabasite was formed under the setting of mid-ocean ridge or adult back-arc basin, and it is the fragment of Paleo-Tethys ophiolite.     

来自蛇绿岩地幔的硫（砷）化物矿物组合

近来在西藏雅鲁藏布江蛇绿岩带的罗布莎蛇绿岩块的地幔豆荚状铬铁矿中发现一个包括金刚石、柯石英、自然元素、合金、氧化物以及硫(砷)化物组成的地幔矿物群。该矿物群的硫(砷)化物具有特殊化学成分并呈包裹体分布在贱金属(BM)和铂族元素(PGE)或它们的合金中,大量化学成分分析得知它们主要由下列元素组成:S、As、Te、Fe、Ni、Co、Cu、Pt、Pd、Ru、Rh、Os、Ir、Mn和Ti。根据化学成分可辨别出约30种硫(砷)化物矿物:FeS、NiS、(Ni,Fe)S、Fe3S2、Ni3S2、(Ru,Os,Ir)S2、Rh7As3、Rh5Ni(Cu)As4、Pd4Rh3As3、Pd8As2、Pd3TeAs、Pd7Te3、RuAs、PtAs2、Ni4Rh3As3、Rh(As,S)2、(Rh,Ir)(As,S)2、Ir(As,S)2、MnS、Ti7S3、Ti7N3、Rh3.5Se3.5CuS2、RhS、Ir2S3、(Ir,Cu)2、S3(Co,Ni,Fe)2(As,S)3、(Ir,Pt)(As,S)2、Ru3(As,S)7以及(BM)x(PGE)yS10-(x y)等,其中包括已定名和未定名的矿物。由于矿物粒度小(<25μm),缺乏X射线分析资料,有待进一步研究。     

西藏日喀则地区蛇绿岩的氦同位素研究

测定了日喀则地区蛇绿岩组合岩石的稀有气体同位素组成。白朗的玄武岩具有比较均一的He同位素组成 ,3He/ 4He平均值为 5 35 9Ra;变橄岩的He同位素比值范围为 1 10 4～ 3 384Ra,平均为 2 383Ra;从东部的仁布和大竹到西部的下鲁和白朗 ,辉绿岩的3He/ 4He由低变高。采于吉定的新鲜辉绿岩平均高达 31 5 7Ra,该值接近于在夏威夷发现的高比值。分步加热法结果显示高R值的He是在低温步释放的 ,根据这种高R值的He可以推测雅鲁藏布江蛇绿岩的成因环境有地幔柱的作用 ,该构造带很可能出现过裂谷洋盆或未能发育成熟的深大裂谷带     

Serpentinites of the Zermatt-Saas ophiolite complex and their texture evolution

The Zermatt‐Saas serpentinite complex is an integral member of the Penninic ophiolites of the Central Alps and represents the mantle part of the oceanic lithosphere of the Tethys. Metamorphic textures of the serpentinite preserve the complex mineralogical evolution from primary abyssal peridotite through ocean‐floor hydration, subduction‐related high‐pressure overprint, meso‐Alpine greenschist facies metamorphism, and late‐stage hydrothermal alteration. The early ocean floor hydration of the spinel harzburgites is still visible in relic pseudomorphic bastite and locally preserved mesh textures. The primary serpentine minerals were completely replaced by antigorite. The stable assemblage in subduction‐related mylonitic serpentinites is antigorite–olivine–magnetite ± diopside. The mid‐Tertiary greenschist facies overprint is characterized by minor antigorite recrystallization. Textural and mineral composition data of this study prove that the hydrated mineral assemblages remained stable during high‐pressure metamorphism of up to 2.5 GPa and 650 °C. The Zermatt‐Saas serpentinites thus provide a well documented example for the lack of dehydration of a mantle fragment during subduction to 75 km depth.     

西藏区域地质基本特征

西藏是青藏高原主体,大地构造位置居于南、北大陆之间的阿尔卑斯—喜马拉雅巨型山系东段,是特提斯构造域的组成部分。本文介绍了西藏区域地层、岩浆岩、变质岩及变质作用、地质构造格局的基本特征,阐述其形成环境及分布特点,从时空角度展示西藏特提斯构造演化历史。     

Comparison of eastern paleo-Tethyan ophiolites and its geodynamic significance——Evidence from Dur’ngoi ophiolite

In global scale, continuous breaking off, drifting apart and re-approaching of supercontinents domi-nated the phanerozoic evolution of lithosphere[1]. Pa-leo-reconstruction reveals that most of continents concentrated in the South Hemisphere to form a su-percontinent[1]. The situation continued until late Pa-leozoic, when the supercontinent broke into Gond-wana in the south and Laurasia in the north. Thereafter the Gondwana experienced continued breaking off and those newly freed blocks drif…