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1.
广东尖山铁矿床内发育了一个完整的钙铝榴石—钙铁榴石系列矿物,它们与矿化有着密切的关系,因此,研究石榴石的标型特征对探讨矿床形成条件是很重要的,对找矿也是有意义的。 一、石榴石的产出特征 尖山矿床赋存在尖山花岗岩体与中—上石炭统壶天群和下二叠统栖霞组碳酸盐岩层的接触带中。从花岗岩体向碳酸盐岩层形成了如下蚀变分带:绿帘石化花岗岩带→透辉石钾长石石英岩带→石榴石透辉石夕卡岩带→石榴石夕卡岩带→钙铁辉石夕卡岩带→大理岩带。钨钼矿化迭加在透辉石钾长石石英岩带中,铁矿化迭加在石榴石夕卡岩和钙铁辉石夕卡岩带中。 相似文献
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万龙山锌锡矿床是都龙锡矿田的一个重要矿区。通过矽卡岩岩石化学研究,认为矿区矽卡岩属于钙矽卡岩,在w(SiO_2)—w(CaO)图解中,矿区矽卡岩与花岗岩、大理岩投点区呈线性展布,表明三者之间具有成因联系。对矿区主要的矽卡岩矿物石榴子石、辉石、角闪石、绿帘石和绿泥石进行了电子探针成分分析:石榴子石属于钙铝榴石-钙铁榴石系列,端元组分以钙铝榴石为主(体积分数51.02%~82.63%),钙铁榴石体积分数为12.45%~47.74%;辉石为透辉石-钙铁辉石系列,端元组分以钙铁辉石为主,明显缺乏透辉石;角闪石属于Mg-Fe-Mn-Li组,主要为镁角闪石;绿帘石中Fe的含量较;绿泥石主要为铁镁绿泥石,部分为铁斜绿泥石、密绿泥石或铁绿泥石,显示富镁铁质的特点。依据矽卡岩矿物的组分特征对矿区矽卡岩的成因、成矿条件及矿床成因等进行了讨论,认为矿区矽卡岩及金属矿化主要与晚白垩世老君山花岗岩具有成因关系,锡锌多金属矿床属于岩浆热液渗透交代型矿床。 相似文献
3.
矽卡岩的一种成因——岩浆成因 总被引:4,自引:0,他引:4
矽卡岩有多种产状、多种成因。已公认的成因观点有:渗滤交代作用、扩散交代作用、热变质作用和同化混染作用。笔者通过多年的工作,提出了由充填作用形成的脉状矽卡岩系岩浆成因的观点。作为矽卡岩浆的依据主要有:1.脉状矽卡岩在易交代岩层中呈充填脉产出;2.与大理岩等围岩的接触界线清楚截然;3.脉旁围岩及脉内角砾很少有蚀变现象;4.脉内可出现花岗岩的矿物组合;5.气孔构造;6.流动构造;7.与硅浆和铁矿浆的产物呈过渡;7.熔融包裹体及熔一流包裹体的存在。笔者认为,矽卡岩浆的形成是由于硅酸盐岩浆同化了碳酸盐地层及含铁地层,并进一步分异的结果。 相似文献
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安徽铜陵狮子山铜矿田岩石的地球化学特征 总被引:1,自引:1,他引:0
安徽铜陵狮子山矿田是铜陵矿集区内储量最大的铜(金)矿田。矿田内矿床类型多样,成矿作用复杂,分布有东狮子山、西狮子山、大团山、老鸦岭、冬瓜山和花树坡等铜(金)矿床。这些矿床均围绕岩体产出,多数为隐伏矿,赋存于上石炭统-中三叠统的不同层位,在空间上具有明显的分带特征,由下向上依次为层控矽卡型、矽卡岩型和热液脉型矿床,其中以前2种类型最为重要。矿田成矿经历了海西期和燕山期2个时代,燕山期为主要成矿期。中酸性侵入岩是狮子山矿田内铜矿床成矿物质的主要来源。该矿田主要岩浆岩为石英闪长岩、辉石二长闪长岩和花岗闪长岩,均为高钾钙碱性系列,属中酸性岩石,为造山带派生的碱性和偏碱性花岗岩。岩石地球化学特征表明本区岩浆岩为幔源岩浆分异的产物,属于壳幔混染型,岩浆岩后期同化围岩使硅质流失,并且在岩浆侵入过程中与Na2O、K2O含量较高的围岩发生了同化混染作用,不同岩石之间可能有某种成因上的联系。 相似文献
6.
冀北水泉沟偏碱性杂岩体中石榴石的特征及其地质意义 总被引:3,自引:0,他引:3
石榴石是冀北水泉沟偏碱性岩体的二长岩类和正长岩类中常见的矿物之一,通过对其产出特征和矿物成分的分析研究,认为石榴石是央浆与大岩岩和片麻岩等围岩反应形成的矽卡岩矿物,从而说明岩浆演化过程曾经历上地壳的同化混染作用,同时也说明成矿过程经历了从矽卡岩阶段→中低温热液阶段,而非单一的中低温热液金矿成矿模式。 相似文献
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福建马坑铁(钼)矿床矽卡岩矿物学特征及分带研究 总被引:3,自引:0,他引:3
马坑大型铁(钼)矿赋存于莒舟-大洋花岗岩体外接触带黄龙组(C2h)灰岩和林地组(C1l)碎屑岩层间构造破碎带中,铁矿与矽卡岩密切共生,但矿床成因尚存在争议。本文就马坑铁矿矽卡岩进行了矿物学特征研究。电子探针分析结果表明:该矿矽卡岩矿物组合主要为辉石、石榴子石和钙蔷薇辉石,退化蚀变岩矿物组合为角闪石、绿帘石、绿泥石、石英等。单斜辉石以透辉石和钙铁辉石为主,仅存在少量锰钙辉石;似辉石为钙蔷薇辉石和蔷薇辉石;石榴子石端元成分以钙铁榴石为主,钙铝榴石少量;角闪石属于钙角闪石,矿物学特征表明它们形成于相对较氧化的条件下。马坑铁矿的矽卡岩是由热流体沿灰岩与碎屑岩之间层间构造破碎带交代形成的,铁矿石大部分产于矽卡岩内,磁铁矿多稍晚于矽卡岩,不仅广泛交代矽卡岩,而且还直接交代灰岩、砂岩等围岩,呈交代结构;主矿体下盘常出现厚层石英岩,碎屑岩也出现了明显的交代,矽卡岩分带现象普遍,与典型矽卡岩矿床特征一致。结合矿床地质特征,马坑铁矿矿床类型应为层控矽卡岩型矿床。 相似文献
8.
青海谢坑铜金矿床石榴石矽卡岩成因研究 总被引:5,自引:0,他引:5
传统矿床学研究认为,只能是中酸性岩浆接触交代碳酸盐岩形成矽卡岩,但是近年来在一系列矽卡岩矿床的研究中发现,矽卡岩原岩并非纯的碳酸盐岩,一些矽卡岩原岩成分接近矽卡岩的成分,因此传统的矽卡岩型矿床成因也值得重新认识。青海省循化县谢坑铜金矿床是20世纪90年代以来发现的石榴石矽卡岩和石榴石透辉石型矽卡岩矿床。通过系统研究该矿床矽卡岩的地球化学特征,发现矿化矽卡岩岩石化学特征及稀土元素、微量元素地球化学特征与泥灰岩和辉石闪长岩类岩浆岩的极其一致,因此该矽卡岩并非传统意义上的矽卡岩,而是热液作用下的岩浆岩及泥灰岩的自变质成因矽卡岩。 相似文献
9.
岩浆矽卡岩及其矿床 总被引:19,自引:0,他引:19
岩浆矽卡岩是由钙硅酸盐熔(流)体或钙矽卡岩质岩浆贯入结晶或/和隐爆团结(结晶)形成的。主要呈脉状体,少数呈角砾岩筒(带),受断裂、裂隙构造控制,可产于各类不同岩石(层)中。岩浆矽卡岩与富碱中基-中酸性侵入岩密切共生,两者在主化学成分上具共轭、互补关系,组成特征的岩浆矽卡岩 -富碱(中基-中酸)侵入岩对。它们是深部高位岩浆房受钙质强烈混染的富碱闪长质岩浆发生不混溶分 离所衍生的两种不同性质的熔(流)体或岩浆的产物。与岩浆矽卡岩有关的各类矿床,主要是含同生铁氧 化物/硫化物液体的钙矽卡岩(矿)浆,伴随其成岩演变的产物,并构成了一个特殊的(岩)浆矽卡岩矿床系列。 相似文献
10.
西藏邦铺超大型钼多金属矿床中矽卡岩铅锌矿体赋存于下二叠统洛巴堆组矽卡岩和大理岩中,矿体呈似层状、透镜状产出,矽卡岩矿物较为发育。为进一步查明矿床矽卡岩矿物种属及矽卡岩类型,剖析矽卡岩形成环境及其与矿化类型之间的关系,基于对矽卡岩矿物系统地显微镜下观测,利用电子探针对矿床主要矽卡岩矿物化学成分进行了系统分析。结果表明,石榴子石端员组分以钙铁榴石为主,含少量锰铝榴石和钙铝榴石;单斜辉石主要为透辉石-钙铁辉石系列,含少量锰钙辉石;似辉石为铁钙蔷薇辉石;角闪石主要为钙质阳起石;绿帘石贫Fe、Mg。矽卡岩矿物组合特征表明,矿床矽卡岩兼具钙矽卡岩和锰质矽卡岩特征;早期矽卡岩形成于较强的氧化环境,成矿岩浆流体亦具有较高氧逸度。邦铺首次发现锰质矽卡岩矿物组合,表明矿区具有银矿找矿潜力,为下一步找矿工作提供了理论支撑。 相似文献
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Fluid metasomatic genesis of stratiform skarn in the Suoerkuduke Cu-Mo deposit,East Junggar,NW China
Stratiform skarns associated with ore deposits are widespread in the north of East Junggar, particularly in the Suoerkuduke Cu-Mo deposit. The Suoerkuduke stratiform and stratoid skarns are hosted by Devonian intermediate-mafic volcanic and pyroclastic rocks, mainly andesite, andesitic porphyry and tuffaceous sandstone, without carbonate or calcareous rocks. The skarns consist of dominant andradite-grossular, epidote, diopside-hedenbergite and minor actinolite, quartz, magnetite and metallic sulfides. The garnet and epidote composition, especially Fe3 + and Al contents, is largely a function of the bulk composition and physicochemical environment (particularly fO2) during crystallization. Such mineralogy indicates a relatively oxidizing environment and medium acidity of solution during skarnization.The Suoerkuduke skarns are distinct from typical contact metasomatic skarn in wall rock, as no carbonate or calcareous rocks were found, and differ in the distribution patterns of skarn zonation in that gradually weakened skarn zones are not quite symmetrically distributed on both sides of the alteration center (a garnet skarn). Abundant remnants of andesite, andesitic porphyry and tuffaceous sandstone in the weakened skarn zone indicate that the protolith of the skarn is andesite, andesitic porphyry and tuffaceous sandstone. Magmatic water, meteoric and seawater are involved in skarn alteration. Moyite and granitic porphyry are not coeval with skarn, and their emplacement resulted in the hornfelization of wall rock instead of skarnization, and themselves keep away from skarn alteration. Therefore, there was probably a huge batholith supplying magmatic fluid for skarn formation. Mass balance estimates suggest that hydrothermal fluid must contribute a portion of Ca and Fe to ensure sufficient supply for skarn formation in the absence of local carbonate and calcareous rocks. In conclusion, the stratiform skarns in the Suoerkuduke are products of intermediate-mafic volcanic and pyroclastic rocks metasomatised by hydrothermal fluid that probably leached calcareous wall rock during ascent. 相似文献
13.
新疆西天山查岗诺尔铁矿床矿物学特征及其地质意义 总被引:12,自引:0,他引:12
查岗诺尔大型磁铁矿床位于西天山阿吾拉勒东段,矿体赋存于下石炭统大哈拉军山组安山质火山碎屑岩或凝灰岩中,主要呈层状、似层状、透镜状,受NW、NWW、NE断裂及环形断裂构造控制。矿区发育石榴石、透辉石、方柱石、阳起石、钾长石、绿帘石、绿泥石、方解石等蚀变矿物,矿石矿物主要为磁铁矿和赤铁矿,伴生的金属矿物以黄铁矿和黄铜矿为主。电子探针分析结果表明,石榴石和辉石分别为钙铁榴石-钙铝榴石系列和透辉石-钙铁辉石系列,其化学组成可表示为Adr37.97~97.89Grs0.19~57.21(Alm+Sps)0.84~4.38和Di28.68~87.46Hd10.46~70.13Jo0.24~5.53,与典型的矽卡岩型铁矿中石榴石和辉石的端员组分相似。在磁铁矿和赤铁矿的Ca+Al+Mn-Ti+V图解中,多数样品落入矽卡岩型铁矿的区域;在磁铁矿的TiO2-Al2O3-MgO图解中,多数样品落入或趋近于沉积变质-接触交代磁铁矿区域。结合矿床地质特征和矿物学研究,认为该矿床的形成与矽卡岩化紧密相关,矽卡岩化对铁成矿有重要的贡献。 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
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雅满苏铁矿床位于东天山中段,矿体赋存于下石炭统雅满苏组安山质火山碎屑岩中,受近EW向断裂及环形断裂构造控制。矿体主要呈层状、似层状、透镜状,近矿围岩蚀变强烈,形成石榴石矽卡岩及复杂矽卡岩。电子探针分析结果表明,石榴石为钙铁榴石-钙铝榴石系列,其化学组成可表示为And45.68~100Gro0.67~57.95(A1m+Sps)11~29.03,与典型的矽卡岩型铁矿中石榴石端员组分相似。在磁铁矿Ca+Al+Mn-Ti+V图解中,大部分样品落入矽卡岩型铁矿区;TiO2-Al2O3-MgO图解中,大多数的样品落入沉积变质接触交代磁铁矿趋势区,部分早期磁铁矿落在岩浆趋势区内。结合矿床地质特征和矿物学研究,认为大多数样品经过了一个热液交代作用过程,表明雅满苏铁矿的形成与岩浆热液交代作用有关。 相似文献
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湖南省永兴县新生矿区隐伏岩体地质地球
化学特征及其与成矿的关系 总被引:1,自引:0,他引:1
[摘 要] 湖南省永兴县新生矿区锡铜多金属矿床是南岭地区典型的矽卡岩型矿床之一,矿体在围
岩、矽卡岩和岩体中均有产出。矿区内地表无岩体出露,但其存在隐伏岩体,该隐伏岩体在深部可能与
大义山岩体相连。岩石地球化学特征表明,矿区K/ Rb 值不到100,说明该区岩浆分异作用强烈,易于成
矿;而铝饱和指数和稀土元素球粒陨石标准化分布型式图则说明矿区铝岩浆来源比较复杂,既有壳源
的,也有壳源混合源的。研究还表明,矿区及大义山岩体为A 型花岗岩,而非之前所认为的S 型花岗岩。
该矿床的形成除受构造特征的控制外,富含Cu、Sn 等成矿元素及F 等挥发组分的岩浆侵位是本区最主
要的控矿因素。 相似文献
17.
Zhou Taofa Wu Mingan Fan Yu Duan Chao Yuan Feng Zhang Lejun Liu Jun Qian Bing Franco Pirajno David R. Cooke 《Ore Geology Reviews》2011,43(1):154-169
The Middle-Lower Yangtze (Changjiang) River Valley metallogenic belt is located on the northern margin of the Yangtze Craton of eastern China. Most polymetallic deposits in the Changjiang metallogenic belt are clustered in seven districts where magmatism of Mesozoic age (Yanshanian tectono-thermal event) is particularly extensive. From west to east these districts are: E-dong, Jiu-Rui, Anqing-Guichi, Lu-Zong, Tong-Ling, Ning-Wu and Ning-Zhen. World-class iron ore deposits occur in the Lu-Zong and Ning-Wu ore clusters, which are mainly located in continental fault-bound volcanic-sedimentary basins. One of these deposits is the Longqiao iron deposit, discovered in the northern part of the Lu-Zong Basin in 1985. This deposit consists of a single stratabound and stratiform orebody, hosted in sedimentary carbonate rocks of the Triassic Dongma'anshan Formation. A syenite pluton (Longqiao intrusion) is situated below the deposit. The iron ore is massive and disseminated and the ore minerals are mainly magnetite and minor pyrite. Wall rock alteration mostly consists of skarn minerals, such as diopside, garnet, potassic feldspar, quartz, chlorite, phlogopite and anhydrite. Thin sedimentary siderite beds of Triassic age occur as relict laminated ore at the top and the margin of the magnetite orebody. These sideritic laminae are part of Triassic evaporite-bearing carbonate deposits (Dongma'anshan Formation).Sulfur isotopic compositions show that the sulfur in the deposit was derived from a mixture of magmatic hydrothermal fluids and carbonate–evaporite host rocks. Similarly, the C and O isotopic compositions of limestones from the Dongma'anshan Formation indicate that these rocks interacted with magmatic hydrothermal fluids. The O isotopic compositions of the syenitic rocks and minerals from the deposit show that the hydrothermal magnetite and skarn minerals were formed from magmatic fluids. The Pb isotopic compositions of sulfides are similar to those of the Longqiao syenite. Phlogopite coexisting with magnetite in the magnetite ores yielded a plateau age of 130.5 ± 1.1 Ma (2σ), whereas the LA-ICP MS age of the syenite intrusion is 131.1 ± 1.5 Ma, which is slightly older than the age of phlogopite.The Longqiao syenite intrusion may have crystallized from a parental alkaline magma, generated by partial melting of lithospheric mantle, during extensional tectonics. The ore fluids were probably first derived from magma at depth, later emplaced in the sedimentary rocks of the Dongma'anshan Formation, where it interacted with siderite and evaporite-bearing carbonate strata, resulting in the formation of magnetite and skarn minerals. The Longqiao iron deposit is a skarn-type stratabound and stratiform mineral system, genetically and temporally related to the Longqiao syenite intrusion. The Longqiao syenite is part of the widespread Mesozoic intracontinental magmatism (Yanshanian event) in eastern China, which has been linked to lithospheric delamination and asthenospheric upwelling. 相似文献
18.
广东大宝山矿田船肚钼钨铜矿床的地质特征、成矿规律与找矿方向 总被引:2,自引:1,他引:1
广东大宝山矿田船肚矽卡岩型钨钼铜矿床受船肚花岗闪长岩体接触带的控制,按空间展布分为北矿带和南矿带。浅部钻探和坑道揭露显示:北矿带裂隙密集,由石英网脉型、构造破碎带型及少量矽卡岩型铜钼矿组成;南矿带为矽卡岩型钨钼矿。蚀变特征和矿化类型及成岩成矿年龄表明,该钼钨矿床是与燕山期花岗闪长岩浆活动有关的中高温热液充填交代矿床,成矿物质来源于花岗闪长岩。通过对有利的赋矿围岩分析、控矿构造解析和与大宝山矿区的控矿要素对比分析,认为船肚岩体是沿着寒武系(顶板)与泥盆系(底板)之间的推覆构造侵入的,靠近花岗闪长岩的内接触带是石英网脉型辉钼矿的有利找矿部位,而云英岩化则是有效的找矿标志。在深部和外围矽卡岩带是船肚矿区南、北矿带探寻矽卡岩型钼钨矿体最具潜力的部位。船肚北矿带次英安斑岩体内部、与斑岩体相连通的成矿前断裂带中和构造虚脱部位、块状和似层状矿体外围的断层、裂隙、节理连通部位及层间滑动虚脱部位都是下一步铜多金属矿找矿的有利部位。文章认为船肚矿区深部存在隐伏铜钼多金属矿体的潜力较大,是大宝山多金属矿田找矿突破的重点地段和重要接替资源区域。 相似文献
19.
江西永平铜矿床蚀变矿化分带、矿石组构及成矿过程 总被引:2,自引:0,他引:2
江西永平铜矿床位于江山-绍兴断裂带南缘、北武夷山燕山早期岩浆岩与海西期-印支期信江断裂坳陷带接合带,是一个伴生S-W-Pb-Zn多矿种的层状铜矿床。逆冲推覆构造控制着矿区内晚古生代地层、燕山期岩浆岩及矿体的空间分布,即基底周潭群逆冲推覆到晚古生界地层上,燕山早期黑云母花岗岩-花岗闪长岩、石英斑岩、花岗斑岩等沿逆冲推覆断面侵入,矿体呈层状产在矽卡岩化石炭系叶家湾组中。矿体围岩主要是石榴石矽卡岩、千枚状页岩及矽卡岩化大理岩。本文从矽卡岩分带、矿石组构等方面来刻画永平铜矿成矿精细过程。永平铜矿矿区的探采工程揭示,以火烧岗岩体为中心向外,蚀变矿物组合、石榴石颜色及矽卡岩的含矿性等表现出明显的分带规律,即从岩体到围岩有:石榴石→透辉石→硅灰石矽卡岩矿物分带;红色→棕色→绿色的石榴石颜色分带;矽卡岩含矿性先增加后降低,其中矿体主要在(红)棕色石榴石矽卡岩呈条带状或网脉状产出。矽卡岩型和变质砂页岩型矿石的矿石矿物组成均与硫化物-石英大脉(~10m)中矿石矿物组成相同或相似,均为黄铁矿-白钨矿-(方铅矿)-闪锌矿-黄铜矿,且生成顺序一致,说明矿区内不同类型的矿石是同一成矿热液体系在不同围岩类型及控矿构造中的产物。永平铜矿成矿过程可划分为石榴石、(磁)赤铁矿阶段、白钨矿阶段、铁铜硫化物阶段、铅锌硫化物阶段和碳酸盐阶段等六个阶段,其中石榴石阶段形成矽卡岩分带,在该阶段晚期形成磁黄铁矿-铁闪石-(黄铜矿)-石英块状矿石;(磁)赤铁矿阶段发育磁铁矿、赤铁矿;白钨矿阶段形成白钨矿及少量黑钨矿;铁铜硫化物阶段是铜硫矿主要矿化阶段,形成块状及脉状黄铜矿矿石;铅锌硫化物阶段是成矿晚期阶段;碳酸盐阶段代表原生成矿过程结束。 相似文献