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铜山铜矿床矿化类型可划分为层状含铜黄铁矿型,含铜角砾岩型,含铜夕卡岩型和含铜班岩型,控矿因素为地层,岩浆岩及构造,其中层间断裂与接触带构造是主要的容矿构造,铅,硫,氢,氧同位素特征及成矿温度研究表明矿物质和热液主要来源于铜山岩体,矿床成因为层控夕卡岩型铜矿床。 相似文献
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曾本兰 《华东地质学院学报》2001,24(4):295-297
福建 地处我国东南沿海,火山岩分布面积广,火山岩型铀矿化类型多,包括火山沉积型、远温地下热水淋滤型、火山期后热液型、富铀次火山岩体热液交代型等。铀矿化表现为多形态、多产状、多部位和多期、 多阶段,矿物 组合简单等特征。赋铀火山岩普遍发育有水解作用,岩石水解后,铀含量增加5-8倍,而分散铀量则减少50-80%。表明火山岩系中铀的活化与岩石的水解作用关切密切。另外,区内火山岩型铀矿化均赋存于火山杂岩系中的反差效应场中,显示出火山杂岩系中的反差效应场与铀的矿化也有密切关系。从总体上看,水解活化、渗析对流和半封闭强反差是福建火山岩型铀矿化的重要成矿机制。 相似文献
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赣东南地区火山地质、矿产特征及找矿方向 总被引:1,自引:0,他引:1
赣东南火山岩区主要发育侏罗纪中、晚世中酸性火山碎屑岩-火山熔岩,其中以爆溢相产出的流纹质晶屑凝灰溶岩分布最广;火山构造主要发育破火山口、岩穹、隐爆角砾岩筒等构造,且与成矿关系;与成矿关系密切的次火山岩广泛发育。区内主要矿化类型为斑岩型、(次火山)隐爆层间裂隙带型、蚀变花岗岩型、隐爆角砾岩型,矿床成因均为与火山活动期后次火山(隐爆)活动有关的岩浆期后高-中温热液交代-充填型矿床。同时,矿床类型上具相互穿插性,隐爆层间裂隙带型、隐爆角砾型等矿床类型往往可以看作是斑岩型矿床的延伸;矿床空间分布上往往具有“一体多型”的特征。新矿化类型是赣南中生代火山岩找矿的重要方向。 相似文献
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成矿作用的本质是成矿流体子系统在统一地质 成矿场中与其它子系统在远离平衡系统的动态过程中所能达到平衡的程度。成矿物质的来源和矿床的富集部位都受新全球动力学理论 -涡旋甩出说以及由它所决定的抽拉构造和多重岩片的控制。 相似文献
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Dolomitization of the Waulsortian Limestone (Lower Carboniferous) in the Irish Midlands 总被引:1,自引:0,他引:1
Jay M. Gregg Kevin L. Shelton Aaron W. Johnson Ian D. Somerville & Wayne R. Wright 《Sedimentology》2001,48(4):745-766
The Waulsortian Limestone (Lower Carboniferous) of the southern Irish Midlands is dolomitized pervasively over a much larger region than previous studies have documented. This study indicates a complex, multistage, multiple fluid history for regional dolomitization. Partially and completely dolomitized sections of Waulsortian Limestones are characterized by finely crystalline (0·01–0·3 mm) planar dolomite. Planar replacive dolomite is commonly followed by coarse (≥0·5 mm) nonplanar replacive dolomite, and pervasive void‐filling saddle dolomite cement is frequently associated with Zn–Pb mineralization. Planar dolomite has average δ18O and δ13C values (‰ PDB) of –4·8 and 3·9 respectively. These are lower oxygen and slightly higher carbon isotope values than averages for marine limestones in the Waulsortian (δ18O=–2·2, δ13C=3·7). Mean C and O isotope values of planar replacive dolomite are also distinct from those of nonplanar and saddle dolomite cement (–7·0 and 3·3; –7·4 and 2·4 respectively). Fluid inclusions indicate a complex history involving at least three chemically and thermally distinct fluids during dolomite cementation. The petrography and geochemistry of planar dolomites are consistent with an early diagenetic origin, possibly in equilibrium with modified Carboniferous sea water. Where the Waulsortian was exposed to hydrothermal fluids (70–280 °C), planar dolomite underwent a neomorphic recrystallization to a coarser crystalline, planar and nonplanar dolomite characterized by lower δ18O values. Void‐filling dolomite cement is isotopically similar to nonplanar, replacive dolomite and reflects a similar origin from hydrothermal fluids. This history of multiple stages of dolomitization is significantly more complex than earlier models proposed for the Irish Midlands and provides a framework upon which to test competing models of regional vs. localized fluid flow. 相似文献
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Abstract: The skarns and genesis were studied of the Huanggang Fe‐Sn deposit and the nearby Sumugou Zn‐Pb deposit in Inner Mongolia, China. In the Huanggang mine, Nos. 1 to 4 Fe ore bodies are arranged along a calcareous horizon from proximal to distal in this order to a granite intrusion named Luotuochangliang, while Sn ore body is situated near another granite intrusion named 204. According to the distance from the granitic intrusions, mineral assemblages in skarns are systematically changed. Garnet is the most predominant skarn mineral throughout the deposit. Hastingsitic amphiboles, however, predominate in the proximal skarns. Fluorite is common in the proximal skarns, while instead calcite is common in the distal skarns. Chlorite is characteristically present only in No. 3 ore body, and chlorite geothermometry gives near 300C for the mineralization of later stage. When garnet crystal shows zonal structure, isotropic andraditic garnet occupies the core, and is surrounded with anisotropic less‐andraditic garnet. The presence of white skarn along the boundary between main skarns and host sedimentary rocks confirms relatively reducing environment prevailing as a whole in the studied area. However, the compositional relation between coexisting garnet and clinopyroxene demonstrates that relatively oxidizing condition was achieved for garnet skarn and magnetite ore in the distal, Nos. 2 to 4 Fe ore bodies and Sumugou deposit, compared to that for garnet skarn in the proximal, No. 1 and Sn ore bodies. Preliminary study on the tin content of garnets in the studied area revealed a certain degree of contribution brought from granitic intrusives since the early stage of skarn formation, irrespective of proximal or distal. Oxygen isotope study on garnet, magnetite, quartz and skarn calcite, as well as hydrogen isotope study on hastingsitic amphibole, demonstrates mainly meteoric water origin for the skarn– and ore‐forming solutions. The occurrence of Sn, W, Mo and F minerals indicates that those elements were mainly supplied to the deposit later than the formation of skarns and iron ores, overlapping to them. These constraints allow to delineate the formation model of the deposit as follows (Fig. 10): At the time of late Jurassic to early Cretaceous, felsic activity occurred in this region as a part of Yanshanian magmatism, and formed granitic intrusions as well as thick volcanic piles on the surface. The circulation of meteoric water was provoked by the heat brought by the intrusions. By this circulation, much amount of iron was extracted from andesites of the Dashizhai Formation, and precipitated as skarns and magnetite ores along calcareous horizons near the bottom of the Huanggangliang Formation. Subsequently, volatile‐rich fluids with Sn, W and Mo were expelled from the solidifying granitic magmas, and precipitated these metals in the pre‐existing skarns and ores. 相似文献