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1.
从地质产状、矿物组合和岩石化学成分等方面探讨了个旧塘子凹接触带不同类型夕卡岩的特征。该夕卡岩带从内侧到外侧常具有辉石夕卡岩带和石榴子石夕卡岩带交替出现的现象,其岩石化学成分也相应地发生韵律变化,表现为在辉石夕卡岩带中SiO2和MgO含量较高,而在石榴子石夕卡岩带中CaO、TFe和Al2O3含量较高。认为夕卡岩带中的韵律变化一方面与被交代围岩中存在灰质白云岩和大理岩的互层带有关,另一方面与岩浆期后热液的渗滤交代作用有关。围岩中的灰质白云岩层被交代后形成辉石带,大理岩层被交代后形成石榴子石带。 相似文献
2.
文章综合分析研究了中国21个夕卡岩矿床中的130个角闪石的成分分析数据。根据夕卡岩类型及其伴生金属矿化的不同,把角闪石分为4大类:钙夕卡岩中的角闪石多属钙角闪石,包括绿钙闪石、铁角闪石、镁绿钙闪石、铁浅闪石、阳起石、铁阳起石、铁镁钙闪石和铁韭闪石等;镁夕卡岩中的角闪石以透闪石为主,局部有浅闪石或韭闪石;锰质夕卡岩中的角闪石有锰质阳起石、锰质透闪石、锰直闪石和锰镁闪石;碱质夕卡岩中的角闪石属钠-钙角闪石或钠角闪石类,包括钠透闪石、镁亚铁钠闪石、亚铁钠闪石、镁铝钠闪石和镁钠闪石。碳酸盐围岩和有关侵入岩的成分对角闪石的类型、成分及其伴生金属矿化起重要的作用。 相似文献
3.
青海西部祁漫塔格地区主要矽卡岩铁多金属矿床成矿地质背景和矿化蚀变特征 总被引:8,自引:2,他引:6
青海西部祁漫塔格地区矽卡岩铁多金属矿床分布广泛,目前已成为中国西部最重要和最有找矿潜力的矽卡岩铁多金属成矿带.在大地构造上,该地区属东昆仑造山带;成矿主要与印支期(204~237Ma)闪长岩、花岗闪长岩和二长花岗岩有关;控矿地层包括蓟县系狼牙山组大理岩、硅质岩,奥陶系-志留系滩间山群大理岩、碎屑岩、硅质岩、中-基性火山岩和石炭系结晶灰岩、碎屑岩等.区内发育3类矽卡岩,即钙矽卡岩、镁矽卡岩和锰质矽卡岩,以前者为主.钙矽卡岩常伴生Fe、Cu、Mo(Pb,Zn)矿化,镁矽卡岩主要伴生Fe矿化,锰质矽卡岩则伴生Pb、Zn(Ag)矿化;矿石矿物组合多种多样,矿化具有一定的分带性.内接触带侵入岩广泛发育钾长石化,与矽卡岩类型一起构成该类矿床的重要找矿标志之一. 相似文献
4.
含金夕卡岩矿床产出构造环境和地质地球化学评价标志 总被引:10,自引:0,他引:10
近十几年来,含金夕卡岩矿床的勘查与研究在国内外取得了很大的进展,发现了一批大型矿床,从而引人注目。含金夕卡岩矿床主要集中分布于环太平洋成矿带,按其产出构造环境可分为三类,即中(新)生代褶皱带、古生代褶皱带和地盾(台)区。控矿地层主要为石炭—二叠系和三叠系碳酸盐岩,次为第三系和寒武系等。有关岩浆岩大多为浅成钙碱性中酸性侵入岩,属Ⅰ型;时代以燕山期和喜山期为主,少数为华力西期、加里东期和印支期。含金夕卡岩绝大多数为钙夕卡岩,只有少数属镁夕卡岩,又可进一步划分为还原型和氧化型。金属矿物组合的特征是常有砷化物、铋化物和碲化物存在,Cu,Au,Ag,As,Bi,Te,Co和Se等元素组合是含金夕卡岩特征性的地球化学标志。矿床(田)常具明显的交代矿化分带,并可构成一定成矿系列,其综合交代矿化分带模式,自岩体向碳酸盐围岩方向依次为:Cu(Mo)→Cu(Fe)→Cu(Au)→Au→Au(Pb,Zn,Ag)。矿物共生组合和流体包裹体研究表明,夕卡岩矿物形成于680~320℃,盐度为w(NaCl)=595%~186%,金的沉淀发生在夕卡岩期后的退化热液交代阶段,大致相当于温度为350~153℃,盐度w(NaCl)=24%~? 相似文献
5.
Geology of gold-bearing skarn deposits in the middle and lower Yangtze River Valley and adjacent regions 总被引:5,自引:0,他引:5
The middle and lower Yangtze River Valley and adjacent regions are the most important metallogenic belt of gold (and copper)-bearing skarn deposits in China. The total gold reserves in this belt have been estimated at more than 600 t. The gold-bearing skarns are mainly distributed in the southeastern Hubei, Tongling and northern Anhui regions. Favorable tectonic settings are depressions and fold zones of the platforms, i.e., mobile belts. These skarns are hosted by platformal limestone, dolomitic limestone and dolomite of the Triassic, Carboniferous-Permian and Middle to Lower Cambrian formations. The related intrusions are Yenshanian (180 to 113 Ma) calc-alkaline quartz monzodiorite, granodiorite, quartz monzonite, monzogabbro, and their hybabyssal facies. The intrusions have high Fe2O3/FeO (>0.5) and intermediate initial 87Sr/86Sr ratios (0.7046 to 0.7087). Their REE distribution patterns are LREE-enriched and exhibit smooth, right-dipping curves. These suggest that the source materials mainly came from upper mantle, with contamination by sialic crustal components. The auriferous skarns are both calcic and magnesian, but calcic skarns are most common. The constituent minerals of the calcic skarns are diopside, garnet, wollastonite, vesuvianite and scapolite, whereas magnesian skarns are dominated by forsterite, spinel, diopside, phlogopite, chondrodite and clinohumite, with abundant superimposed serpentine, clinochlore and brucite. The compositions of coexisting pyroxenes and garnets are diopside and andradite, indicating the high oxygen fugacity and low acidity conditions. Gold is closely associated with Cu (Pb, Zn) sulfides and exists mainly in the form of native gold and electrum. Arsenides, tellurides, bismuthides and selenides are present in many ore deposits. Therefore, Cu, As, Bi, Te, Ag, Pb, Zn, Se and Co are the major metals present in the deposits and are important geochemical ore-searching indicators. In some Au (Fe, Cu) magnesian skarns, magnesiomagnetite, magnesioferrite and ludwigite are locally abundant. The metasomatic zoning in many gold skarn deposits is very distinct consisting of an outward sequence of: Fe (Cu)→Cu (Mo)→Cu (Au)→Au (Cu)→Au (Pb, Zn). The geologic characteristics of Au (Cu) skarn deposits that formed in the mobile platformal setting of China have distinct differences compared to Au skarns formed in orogenic belts at convergent plate margins in British Columbia and the western USA. 相似文献
6.
7.
The paper presents systematized and synthesized data on the parameters and evolutionary sequence of metasomatic processes that accompanied interaction between Permian–Triassic trap complex and rocks of the sedimentary cover of the Siberian Platform at the large skarn iron deposits. Relations of the textural–compositional, morphological, and genetic diversity of the skarns and ores with the phases and stages of the origin of ore-bearing volcano-tectonic edifices are demonstrated with reference to the Korshunovskoe and Rudnogorskoe deposits. The genetic reconstructions are based on survey materials and data on the mineralogy of the rocks and ores (obtained by optical and scanning electron microscopy, microprobe analysis, EPR, Raman and IR spectroscopy, and by studying inclusions in minerals). A principally important feature of the volcano-tectonic edifices of the large mineral deposits is their multistage evolution and combinations of fluid-conducting zones, which are related to (1) volcanic apparatuses, (2) shallow-depth magmatic chambers (laccoliths) hosted in carbonate–salt rocks, and (3) multistage fracture structures produced by the collapse of the leached space. The major ore-bearing structures were formed simultaneously with the development of an intermediate magmatic chamber hosted in Cambrian carbonate–salt rocks beneath a seal of terrigenous sedimentary rocks. Magmatic-stage magnesian skarns with disseminated ores in them and in the calciphyres were produced during the prograde stage in the apical parts of the laccoliths, at contacts between the dolerites and dolomites. During the early prograde stage, skarn–ore bodies developed around injection bodies of globulated dolerites, laccoliths, and sills; stockworks and steep bodies of fragmentary magnesian and calcic skarns and ores were formed within the diatremes; and conformable bodies and veins were produced in the splay fracture zones. The later reactivation of faults and fractures and the involvement of connate brines and solutions from the evaporite complex triggered the redeposition of the ore masses, crystallization of the mineral assemblages of hydrated skarns, development of large domains of serpentine–chlorite–epidote–amphibole rocks, calcic skarns, and ores. Data on multiphase fluid inclusions in the forsterite, apatite, and halite indicate that the mineral-forming fluid initially was a highly concentrated solution–melt (total salinity of 60%) with high-density reduced gases. The magnesian skarns were formed during the following stages: (1) forsterite + fassaite + spinel + first-population magnetite (820–740°C); (2) phlogopite + titanite + pargasite + second-population magnetite (600–500°C), and (3) clinochlore + serpentine + tremolite + pyrrhotite + chalcopyrite (≥450°C). 相似文献
8.
The Nanling Range in South China hosts numerous world-class W–Sn deposits and some Fe deposits. The Mesozoic Tengtie Fe skarn deposit in the southern Nanling Range is contemporaneous with the regional Sn mineralization. The deposit is composed of numerous ore bodies along the contacts between the late Paleozoic or Mesozoic carbonate rocks and the Yanshanian Lianyang granitic complex. Interaction of the magma with hosting dolomitic limestone and limestone formed calcic (Ca-rich) and magnesian (Mg-rich) skarns, respectively. The Tengtie deposit has a paragenetic sequence of the prograde stage of anhydrous skarn minerals, followed by the retrograde stage of hydrous skarn minerals, and the final sulfide stage. Magnetite in the prograde and retrograde skarn stages is associated with diopside, garnet, chlorite, epidote, and phlogopite, whereas magnetite of the final stage is associated with chalcopyrite and pyrite. Massive magnetite ores crosscut by quartz and calcite veins are present mainly in the retrograde skarn stage. Laser ablation ICP-MS was used to determine trace elements of magnetite from different stages. Some magnetite grains have unusually high Ca, Na, K, and Si, possibly due to the presence of silicate mineral inclusions. Magnetite of the prograde stage has the highest Co contents, but that of the sulfide stage is extremely poor in Co which partitions in sulfides. Magnetite of magnesian skarns contains more Mg, Mn, and Al than that of calcic skarns, attributed to the interaction of the magma with compositionally different host rocks. Magnetite from calcic and magnesian skarns contains 6–185 ppm Sn and 61–1246 ppm Sn, respectively. The high Sn contents are not due to the presence of cassiterite inclusions which are not identified in magnetite. Instead, we believe that Sn resides in the magnetite structure. Regionally, intensive Mesozoic Sn mineralization in South China indicates that concurrent magmatic–hydrothermal fluids may be rich in Sn and contribute to the formation of high-Sn magnetite. Our study demonstrates that trace elements of magnetite can be a sensitive indicator for the skarn stages and wall-rock compositions, and as such, trace elemental chemistry of magnetite can be a potentially powerful fingerprint for sediment provenance and regional mineralization. 相似文献
9.
10.
镁质碳酸盐岩型温石棉矿床是成矿热液交代镁质碳酸盐岩生成的,一般均产于地台环境。按地台稳定性不同,成矿环境分为地台隆起区的基底建造类型和地台拗陷区的盖层建造类型。产于地台隆起区的矿床,以前震旦纪镁质碳酸盐岩为控矿层位。产于太古代及早、中元古代深变质结晶基底中的矿床,由区域变质及混合岩化过程中的变质热液交代碳酸盐岩成矿。产于晚元古代浅变质褶皱基底(扬子准地台)中的矿床,以岩浆期后热液或接触交代(湿矽卡岩)热液为成矿热液来源。产于地台拗陷区的矿床,均以震旦纪镁质碳酸盐岩为控矿层位。其成矿时期较晚,一般与拗陷区内岩浆活动同期,由岩浆期后热液或接触交代(湿矽卡岩)热液对镁质碳酸盐岩进行交代成矿。 相似文献
11.
S. M. Aleksandrov 《Geochemistry International》2011,49(7):711-725
The results of skarn-forming processes at contacts of the multiphase Southern California Batholith with carbonate rocks accessible
to study in quarries in Riverside, California, involve prograde metasomatic transformations of marmorized dolomites and calcareous
rocks in contact with granitic melts and contaminated magmas. The processes of contact assimilation are proved to have been
controlled by the emplacement of granitic melts overheated relative to subliquidus melts (with the overheated melts prone
to approach the composition of granodiorite, syenite, and gabbro) into skarnified marbles. The degree of magma overheating
was evaluated based on G.F. Smith’s data on linear melting temperature variations for anhydrous intrusive rocks with various
SiO2 concentrations (<750°C for granites and >1100°C for contaminated rocks, ΔT 350°). This corresponds to the thermal regime of the development of mineralogically contrasting hypabyssal skarn aureoles:
magnesian at contacts with granite magmas and calcic at contacts with melts of high basicity. The peripheral parts of the
aureoles ubiquitously contain preserved zones of forsterite calciphyres and periclase marbles, whereas skarns at mafic intrusions
consist of high-temperature silicates of decreasing Mg contents: monticellite, merwinite, melilite, and spurrite. Prograde
and retrograde mineralforming processes in the metasomatic rocks and their facies affiliation are analyzed, and the chemical
composition of the minerals are examined. The Riverside skarn aureoles are compared with other compositionally contrasting
skarn aureoles that developed in contacts with granite magmas and melts of increasing basisity. 相似文献
12.
Abundant iron oxide deposits including banded iron formations, apatite iron oxide ores, and enigmatic marble/skarn-hosted magnetite deposits occur in the Palaeoproterozoic Bergslagen region, southern Sweden. During the last 100 years, the latter deposit class has been interpreted as contact metasomatic skarn deposits, metamorphosed iron formations, or metamorphosed carbonate replacement deposits. Their origin is still incompletely understood. At the Smältarmossen mine, magnetite was mined from a ca. 50-m-thick calcic skarn zone at the contact between rhyolite and stratigraphically overlying limestone. A syn-volcanic dacite porphyry which intruded the footwall has numerous apophyses that extend into the mineralized zone. Whole-rock lithogeochemical and mineral chemical analyses combined with textural analysis suggests that the skarns formed by veining and replacement of the dacite porphyry and rhyolite. These rocks were added substantial Ca and Fe, minor Mg, Mn, and LREE, as well as trace Co, Sn, U, As, and Sr. In contrast, massive magnetite formed by pervasive replacement of limestone. Tectonic fabrics in magnetite and skarn are consistent with ore formation before or early during Svecokarelian ductile deformation. Whereas a syngenetic–exhalative model has previously been suggested, our results are more compatible with magnetite formation at ca. 1.89 Ga in a contact metasomatic skarn setting associated with the dacite porphyry. 相似文献
13.
安徽贵池铜山矽卡岩型铜矿床蚀变矿化分带特征及其成因 总被引:6,自引:1,他引:5
铜山矽卡岩型铜矿床产于长江中下游铁铜成矿带中的安庆—贵池矿集区。研究区矽卡岩化与矿化发生于碳酸盐岩地层与花岗闪长斑岩间的接触带中,蚀变及矿化具有水平与垂向分带特征。水平方向上,靠近岩体的矽卡岩中石榴子石含量较高,远离岩体的矽卡岩中透辉石含量较高;靠近大理岩带发育钙铁辉石矽卡岩,远离大理岩带的灰岩硅化较强。垂向上,从上到下依次为角岩带、钙质矽卡岩带和镁质矽卡岩带。矿物成分研究表明,靠近岩体处氧化性较强,石榴子石的钙铁榴石端员含量高;铜多富集于含石英脉的岩体、距岩体略远的矽卡岩、角岩或大理岩中,而锌多富集于硅化灰岩及远离岩体的矽卡岩中。研究表明,该矿床中蚀变矿化经历了进变期和退变期,包括接触热变质阶段、进化交代阶段和早退化蚀变阶段、晚退化蚀变阶段。其中,大规模的黄铜矿化主要发生于早退化蚀变阶段,且在岩浆演化晚期进一步富集于斑岩石英脉中。 相似文献
14.
环太平洋地区的矽卡岩矿床 总被引:4,自引:1,他引:4
环太平洋地区是世界上最重要的巨型矽卡岩矿床成矿带。在地跨亚、美、澳三大洲二十多个沿岸国家中,共分布有一千多个不同类型的矽卡岩矿床。按含矿矽卡岩主要金属元素的不同,可把本区矽卡岩矿床划分为铁、铜、铅-锌、钨、锡、钼、金七类。文中对各类矽卡岩矿床的分布和主要地质特征作了概括介绍。按含矿矽卡岩矿物组合的不同,又可分为镁矽卡岩型、钙矽卡岩型、锰质矽卡岩型和碱质矽卡岩型四类。太平洋东西两岸的矽卡岩矿床有许多共同点,但在矿化强度、分布规律和成矿时代等方面又有一定差异。文中还论述了本区矽卡岩矿床的成矿系列和岩浆岩成矿金属性问题。 相似文献
15.
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
16.
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
17.
The Tongshan skarn-type copper deposit is located in the Anqing–Guichi ore cluster of the iron–copper metallogenic belt which occurs along the Middle–Lower Yangtze River Valley, China. In the study area, skarnization and mineralization took place along the contact zone between carbonates and granodiorite porphyries. The contact zone shows significant horizontal and vertical variations in alteration and mineralization. In the horizontal direction, the garnet content is high in the skarns near the intrusive body (proximal skarns), the diopside content is high farther from the intrusive body (distal skarns), and hedenbergite is concentrated in the skarns adjacent to the marble zone. Limestones located far from the marble zone experienced a strong silicification. In the vertical direction (from higher to lower levels), the rocks change from hornfels to calcareous skarn to magnesian skarn. Mineralogical studies show that the skarns near the intrusion are relatively oxidized, and the garnet in the skarns is relatively andradite rich. High concentrations of Cu are found in the porphyries with quartz veins, as well as in the calcic skarns, magnesian skarns, hornfelses, and marbles, which are located at distances of 13, 10, 43 and 25 m from the porphyries, respectively. High concentrations of Zn are found in silicified limestones and skarns located even farther from the porphyries. The present findings suggest that the Tongshan deposit was subjected to prograde alteration and mineralization, followed by retrogression. The alteration can be divided into a sequence of stages: contact metamorphism, prograde metasomatism, early retrogression, and late retrogression. The copper mineralization occurred mainly during the early retrogression, and the copper was further enriched in quartz veins within the porphyries during the late stages of magma evolution. 相似文献
18.
Variations in the composition and mineral assemblages of boronaluminosilciates (serendibite, grandidierite, kornerupine, and tourmaline) were studied in the abyssal and hypabyssal skarns of New York and California, United States, the Taezhnyi deposit of southern Yakutia, and deposits of the Pamirs, and compared to their occurrences around the world. The genesis of the boronaluminosilicates depends on the facies of the replaced skarns and the calcareous-skarn alteration of the primary composition of the host rocks. The substitution between Mg and Fe, as well as between Al, Si, and B, was studied in complex boronaluminosilciates and associated minerals. It was shown that f of serendibite is determined by that in the replaced skarn minerals (pyroxenes, spinel, sapphirine, and grandidierite) and is inherited in the replacing tourmaline and late silicates. Unlike serendibite, kornerupine is a typomorphic mineral of only bimetasomatic skarns of the abyssal facies. Serendibite, grandidierite, kornerupine, and tourmaline crystallized during the postmagmatic stage of the evolution of boron mineralization at skarn deposits of both the abyssal and the hypabyssal facies, at contact with magnesian carbonate sequences and desilicified aluminosilicate rocks. 相似文献
19.
The mineralogy of copper-bearing skarn to the east of the Sungun-Chay river, East-Azarbaidjan, Iran 总被引:2,自引:0,他引:2
A calcic copper-bearing skarn zone in East-Azarbaidjan, NW of Iran is located to the east of the Sungun-Chay river. Skarn-type metasomatic alteration and mineralization occurs along the contact between Upper Cretaceous impure carbonates and an Oligo-Miocene Cu-bearing granitoid stock. Both endoskarn and exoskarn are developed along the contact. Exoskarn is the principal skarn zone enclosed by a marmorized and skarnoid–hornfelsic zone. The skarnification process occurred two stages: (1) prograde and (2) retrograde. The prograde stage is temporally and spatially divided into two sub-stages: (a) metamorphic–bimetasomatic (sub-stage I) and (b) prograde metasomatic (sub-stage II). Sub-stage I began immediately after the intrusion of the pluton into the enclosing impure carbonates. Sub-stage II commenced with segregation and evolution of a fluid phase in the pluton and its invasion into fractures and micro-fractures of the marmorized and skarnoid–hornfelsic rocks developed during sub-stage I. The introduction of considerable amounts of Fe, Si and Mg led to the development of substantial amounts of medium- to coarse-grained anhydrous calc-silicates. From texture and mineralogy the retrograde metasomatic stage can be divided into two discrete sub-stages: (a) early (sub-stage III) and (b) late (sub-stage IV). During sub-stage III, the previously formed skarn zones were affected by intense multiple hydro-fracturing phases in the Cu-bearing stock. In addition to Fe, Si and Mg, substantial amounts of Cu, Pb, Zn, along with volatile components such as H2S and CO2 were added to the skarn system. Consequently considerable amounts of hydrous calc-silicates (epidote, tremolite–actinolite), sulfides (pyrite, chalcopyrite, galena, sphalerite, bornite), oxides (magnetite, hematite) and carbonates (calcite, ankerite) replaced the anhydrous calc-silicates. Sub-stage IV was concurrent with the incursion of relatively low temperature, more highly oxidizing fluids into skarn system, bringing about partial alteration of the early-formed calc-silicates and developing a series of very fine-grained aggregates of chlorite, clay, hematite and calcite. 相似文献