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1.
西藏尕尔穷铜金矿金矿物特征研究 总被引:7,自引:0,他引:7
尕尔穷铜金矿床是班公湖-怒江成矿带西段第一个达到详查程度的矽卡岩型铜金矿床。通过对矿床中金矿物的电子显微镜观察和扫描电镜能谱分析,查明了金矿物的类型及赋存状态,划分了成矿阶段。研究表明,金矿物有银-金矿物系列、铜-金矿物系列和少量碲化物类,主要有自然金、银金矿、金银矿、铜质金银矿、铜金矿、铜质银金矿和碲金银矿。金矿物主... 相似文献
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广东石人嶂钨矿床中的晶质铀矿研究 总被引:5,自引:0,他引:5
石人嶂钨矿床含钨石英脉、花岗岩、云英岩中均发育有晶质铀矿。岩矿鉴定及EDS分析研究发现,铀矿与钍石构成类质同象系列(包括晶质铀矿、含钍晶质铀矿、铀钍石、含铀钍石、钍石、方钍石),它们常常与黄铁矿、磷钇矿、锆石、独居石等矿物共生。晶质铀矿成分在不同矿脉、不同中段均有变化,矿物内部成分也不稳定,可发育生长环带。XRD分析确认晶质铀矿的存在,主要成分是UO2。随着热液活动的增强,矿物颗粒的增大,晶质铀矿成分变纯,UO2含量增加;晶质铀矿常常形成黄铁矿边,次生变化在边部析出富含杂质的铀矿微粒。电子探针测试晶质铀矿的年龄为151~157Ma,与本区钨矿化年龄相吻合,跟华南地区铀矿化构成同一成矿系列,同属于燕山期成矿大爆发阶段同一成矿热液活动的产物,这对于在该地区钨矿床及外围寻找铀矿资源具有重要意义。 相似文献
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位于扬子地块西南缘康滇地轴的拉拉矿床是我国典型的铁氧化物-铜-金-铀(IOCG)矿床。该矿床主要产出铁铜矿石,并共(伴)生有一定规模的铀矿化。本文在野外地质调查的基础上,综合利用微区X射线荧光光谱法(μ-XRF)、扫描电镜(SEM)、电子探针(EPMA)和激光剥蚀电感耦合等离子体质谱法(LA-ICP-MS)等测试技术,针对拉拉矿床中的铀矿化开展了详细的矿相学、地球化学和同位素年代学研究,并进一步探讨了铀成矿构造背景和成矿环境。研究表明,晶质铀矿、钛铀矿和铀石是拉拉矿床中主要的铀矿物,晶质铀矿同时产于铁铜矿石和铀矿化样品中,但钛铀矿和铀石仅产于铀矿化样品中。晶质铀矿主要呈立方体晶形产出,具有高U、Pb和Y,低Th、Ca、Si、Ti和P的地球化学组成,属于低钍晶质铀矿。U-Pb同位素定年表明拉拉矿床发育两期铀矿化,早期铀矿化产于铁铜矿石中,形成年龄为990±4 Ma,与早期铁铜矿化(~1.05 Ga)同步,晚期为后期叠加的热液铀矿化,以晶质铀矿-方解石-萤石脉的形式穿插于铁铜矿石中,形成年龄为~850 Ma,与晚期铁铜矿化(~850 Ma)同步,早晚两期矿化分别形成于大陆裂谷环环境和活动大... 相似文献
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电子探针化学测年在攀枝花大田晶质铀矿中的应用及其意义 总被引:1,自引:1,他引:0
晶质铀矿和沥青铀矿是热液铀矿床的主要工业铀矿物,在研究热液铀矿床成因及成矿规律方面具有重要的意义。攀枝花大田地区是我国混合岩型热液铀矿分布区,已发现粗粒特富铀矿滚石(铀含量10%)及较富基岩矿石(铀含量为0.1%~2%),主要铀矿物为晶质铀矿,对两种晶质铀矿成分及形成时代的研究对该区混合岩型热液铀矿成矿规律研究具有重要的价值。本文通过对大田地区滚石中的晶质铀矿和基岩矿石中的晶质铀矿进行矿物学及电子探针分析,研究了晶质铀矿的成分及形成时代。结果表明:(1)大田地区滚石和基岩矿石中的晶质铀矿除铅之外化学成分较为相似,两类矿石晶质铀矿中UO_2含量为77.36%~84.04%,ThO_2含量为0.98%~5.59%,PbO含量为1.79%~8.8%,其中滚石晶质铀矿中的铅含量低于基岩晶质铀矿,钍含量高于基岩晶质铀矿;(2)电子探针化学定年结果表明,基岩矿石晶质铀矿的形成时代为774.9~785.5 Ma,滚石晶质铀矿的形成时代为783.7 Ma,与传统同位素测年结果(775~777.6 Ma)非常一致,一方面说明滚石晶质铀矿和基岩晶质铀矿为同一时代的产物,另一方面说明电子探针原位测年方法是可靠的;(3)在后期的热液蚀变中,晶质铀矿先后发生了硅化、碳酸盐化及赤铁矿化,蚀变发生的时间分别为730.6Ma、699.8 Ma和664.0 Ma。此结论对研究攀枝花大田地区热液铀矿成矿时代及成矿作用过程提供了依据。 相似文献
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紫云山岩体是赣中地区与钨铀成矿关系极为密切的过铝质花岗岩体,但目前该岩体的成岩时代尚不明确.通过偏光显微镜、扫描电镜、电子探针等手段,首次开展了紫云山花岗岩中赋存晶质铀矿的精细矿物学研究.结果表明:晶质铀矿主要赋存于黑云母之中,少数被黄铁矿包裹,部分晶质铀矿被不同程度溶蚀和交代,表明晶质铀矿是本区花岗岩型铀矿的主要铀源矿物之一.利用电子探针U-Th-Pb化学定年法测得蕉坑单元 (J3J)5颗晶质铀矿年龄为154.5~168.9 Ma,加权平均年龄为161.8±2.4 Ma (MSWD=0.26,n=26),庙前单元 (J3M) 三颗晶质铀矿年龄为152.8~164.7 Ma,加权平均年龄为159.7±3.2 Ma (MSWD=0.2,n=15).获得的年龄与南岭地区主要含钨花岗岩的侵入时间高度一致,对应华南中生代大规模岩浆活动的第二阶段.晶质铀矿年龄与华南含钨花岗岩锆石U-Pb年龄非常一致,验证了过铝质富铀花岗岩中晶质铀矿电子探针定年方法的可行性. 相似文献
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鄂东南地区鸡冠嘴铜金矿床Au-Ag-Bi-Te-Se矿物学研究与金银富集机理 总被引:5,自引:3,他引:2
鸡冠嘴铜金矿床是鄂东南地区典型的矽卡岩型铜金矿床。矿体主要赋存于下三叠统大冶组大理岩中,矿石矿物以黄铜矿和黄铁矿及少量金银矿物为主,与矿化有关的蚀变包括矽卡岩化、硅化、绿泥石化、碳酸盐化、钾长石化等。根据野外观察和镜下鉴定将成矿过程划分为干矽卡岩阶段、湿矽卡岩阶段、硫化物阶段和碳酸盐阶段,其中硫化物阶段为金矿化的主要阶段。矿相学研究、扫描电子显微镜-能谱分析和电子显微探针分析结果表明,主要载金矿物为黄铜矿和黄铁矿,金的赋存状态包括可见金和不可见金,可见金以银金矿为主,其次为自然金和含银自然金,不可见金为纳米级自然金。主要载银矿物是黄铜矿和斑铜矿,银矿物多以可见银(硒银矿、碲银矿和辉银矿等)产出,包括独立银矿物和显微包体银;不可见银主要以次显微包体的形式分布于硫化物中。鸡冠嘴铜金矿床是高温岩浆热液与碳酸盐岩地层发生接触交代作用形成的,Au在高温热液中可能主要以氯络合物、碲络合物或碲化物熔体的形式搬运。随着矽卡岩化等蚀变作用的进行和热液温度的降低,热液中氯被消耗的同时硫逸度快速上升,Au主要以金硫络合物的形式在热液中运移,硫化物阶段早期大量Bi-Te-S矿物及少量纳米级自然金以显微包裹体的形式包裹于近于同时沉淀的黄铁矿中,随后碲银矿、辉银矿及硫铋铜矿与硫化物及石英和碳酸盐矿物共生产出。成矿流体演化过程中由于温度和硫逸度的进一步降低导致金络合物不稳定,当Logf Te2-20且-14Logf Se2-10时,金矿物与硒化物与黄铜矿近于同时沉淀,或充填于先期沉淀的黄铁矿微裂隙和其他矿物之间的空隙中。综合分析表明,鸡冠嘴铜金矿床成矿过程中Te和Bi对Au的富集具有重要重用。 相似文献
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辽东地区是中国成矿时代最古老的铀矿矿集区,有单铀型和铁矿伴生型两种,其中单铀型矿床成矿年龄已基本厘定,而铁矿伴生型铀矿成矿年龄尚不明确,制约了该类矿床的成因认识。晶质铀矿是铁矿伴生型铀矿中最主要的含铀矿石矿物,对其开展测年能够直接厘定铀矿成矿时代。本文对翁泉沟富蛇纹石磁铁矿矿石和弓长岭石榴子石蚀变岩中的晶质铀矿进行电子探针(EPMA)测年,并利用激光剥蚀电感耦合等离子体质谱法(LA-ICP-MS)对翁泉沟富蛇纹石磁铁矿矿石中的晶质铀矿进行U-Pb测年,两种测年结果相互验证,获得辽东地区铁矿伴生型铀矿的成矿时代为~1.85Ga,并在~1.78Ga遭受了后期热液事件的改造,与单铀型矿床成矿年龄一致,说明辽东地区单铀型和铁矿伴生型铀矿都形成于碰撞后伸展环境。辽东地区铁矿伴生型铀矿不同矿床的成矿热液在流体成分和温度上有差别,但都具有碱性和氧化的特征。 相似文献
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粤北产铀与不产铀花岗岩中铀矿物特征的电子探针研究及其找矿意义 总被引:1,自引:0,他引:1
晶质铀矿的含量、形貌、成分、铀矿物类型、与铀矿物共存的矿物组合等特征可以作为产铀与不产铀岩体的判别标志,为花岗岩型铀矿找矿工作提供了一种新的技术手段。长江岩体和九峰岩体是粤北地区典型的产铀与不产铀花岗岩体,本文利用电子探针测试了九峰岩体的铀矿物并与长江岩体进行对比研究。结果表明九峰岩体的铀矿物主要为晶质铀矿,其化学年龄可分为两组,分别为~160 Ma、~105 Ma,与长江岩体的两组晶质铀矿年龄基本一致;其中第一组年龄代表岩体的成岩年龄,第二组年龄与粤北地区~105 Ma的基性岩脉侵入时代相对应;但九峰岩体缺少长江岩体中~74 Ma的成矿年龄。相比于长江岩体,九峰岩体的铀矿物受到后期热液事件的影响较小,U没有发生明显的活化、转移,因而未能富集成矿,没有形成具有工业价值的铀矿床。 相似文献
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鄂东南鸡笼山矽卡岩型金铜矿床金、银、碲、铋的赋存状态及其对成矿条件的制约 总被引:1,自引:0,他引:1
鸡笼山矽卡岩型金铜矿床是长江中下游成矿带典型的矽卡岩矿床,矿体主要赋存于下三叠统大冶组碳酸盐岩与花岗闪长斑岩接触带内。根据野外观察和镜下鉴定,将成矿过程划分为进矽卡岩阶段、退化蚀变阶段、石英-硫化物阶段和碳酸盐阶段,其中石英-硫化物阶段为金和铜的主要成矿阶段。鸡笼山金铜矿床中不同类型矿石的矿相学观察和电子探针微区成分分析(EPMA)表明,金、银主要以自然金、银金矿、碲银矿、硫银铋矿等形式产出,主要载金矿物为黄铜矿和黄铁矿;同时发现鸡笼山金铜矿床中发育大量碲-铋矿物(如辉碲铋矿、针硫铋铅矿等)。成矿流体物理化学性质研究表明,鸡笼山金铜矿床中金银元素在高温热液中主要以氯络合物的形式运移,随着温度降低和流体进一步的演化,金银元素转变为以硫络合物、碲铋化物熔体等形式运移。在石英-硫化物阶段,由于硫化作用与流体的沸腾作用,流体中硫逸度降低,碲逸度升高;当流体处于黄铁矿-磁黄铁矿氧逸度范围、酸碱性呈中性-弱碱性、碲逸度(logf_(Te2))为-10.7~-8.4、硫逸度(logf_(S_2))为-11.4~-10.6时,金、银、铜元素近于同时沉淀,碲、铋和砷元素对金和银元素运移和富集起到了重要作用,最终形成了鸡笼山矽卡岩型金铜矿床。 相似文献
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SONG Huanbin HE Mingqin ZHANG Shangzhong YI Fenghuang 《中国地球化学学报》2008,27(1):104-108
The Jingbaoshan platinum-palladium deposit is China's largest independent PGM (platinum-group metals) deposit so far discovered. There are eleven kinds of useful components in the ore: Pt, Pd, Os, Ir, Ru, Rh, Au, Ag, Cu, Ni, and Co. The platinum-group elements, gold and silver occur in the form of minerals in ores. twenty-five kinds of precious metal minerals have been found, of which twenty one belong to the platinum-group minerals. The minerals are very small in grain size. Copper occurs mainly as copper sulfide with a small amount of free copper oxide, and the beneficiated copper accounts for 95.21%. Nickel occurs mainly as nickel sulfide, and some nickel silicate and nickel oxide occur in the ore. The beneficiated nickel accounts for 72.03%. Cobalt occurs mainly as cobalt sulfide, and there are some cobalt oxide and other kinds of cobalt. The beneficiated cobalt accounts for 77.58%. 相似文献
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Yu. A. Poltavets V. N. Sazonov Z. I. Poltavets G. S. Nechkin 《Geochemistry International》2006,44(2):143-163
Relationships between noble-metal and oxide-sulfide mineralization during the origin of the Volkovsky gabbroic pluton are discussed on the basis of geochemical data and thermodynamic calculations. The basaltic magma initially enriched in noble metals (NM) relative to their average contents in mafic rocks, except for Pt, is considered to be a source of Pd, Pt, Au, and Ag in the gabbroic rocks of the Volkovsky pluton. The ores were formed with a progressive gain of NM in the minerals during the fractionation of the basaltic magma. The active segregation of NM in the form of individual minerals (palladium tellurides and native gold) hosted in titanomagnetite and copper sulfide ore occurred during the final stage of gabbro crystallization, when the residual fluid-bearing melt acquired high concentrations of Cu, Fe, Ti, and V, along with volatile P and S. Copper sulfides—bornite and chalcopyrite—are the major minerals concentrating NM; they contain as much as 22.65–25.20 ppm Pd and 0.74–1.56 ppm Pt; 4.39–8.0 ppm Au, and 127.2–142.6 ppm Ag, respectively. The copper ore and associated NM mineralization were formed at a relatively low sulfur fugacity, which was a few orders of magnitude (attaining 5 log units) lower than that of the pyrite-pyrrhotite equilibrium. The low sulfur fugacity and the close chemical affinity of Pd and Pt to Te precluded the formation of pyrrhotite, pyrite, and PGE disulfides. The major ore minerals and NM mineralization were formed within a wide temperature range (800–570°C), under nearly equilibrium conditions. Foreign elements (Ni, Co, and Fe) affected the thermodynamic stability of Pd and Pt compounds owing to the difference in their affinity to Te and to elements of the sulfur group (S, Se, and As). The replacement of Pd with Ni and Co and, to a lesser extent, with Pt and the replacement of Te with S, As, and Se diminish the stability field of palladium telluride. Comparison of Pd tellurides from copper sulfide ores at the Volkovsky and Baronsky deposits showed the enrichment of the former in Au, Sb, and Bi, while the latter are enriched in Pt, Ni, and Ag. The enrichment of Pd tellurides at the Baronsky deposit in Ni is correlated with the analogous enrichment of the host gabbroic rocks. 相似文献
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The Kaalamo massif is located in the Northern Ladoga region, Karelia, on the extension of the Kotalahti Belt of Ni-bearing ultramafic intrusions in Finland. The massif, 1.89 Ga in age, is differentiated from pyroxenite to diorite. Nickel–copper sulfide mineralization with platinoids is related to the pyroxenite phase. The ore consists of two mineral types: (i) pentlandite–chalcopyrite–pyrrhotite and (ii) chalcopyrite, both enriched in PGE. Pd and Pt bismuthotellurides, as well as Pd and Pt tellurobismuthides, are represented by the following mineral species: kotulskite, sobolevskite, merenskyite, michenerite, moncheite, keithconnite, telluropalladinite; Pt and Pd sulfides comprise vysotskite, cooperite, braggite, palladium pentlandite, and some other rare phases. High-palladium minerals are contained in pentlandite–chalcopyrite–pyrrhotite ore. Native gold intergrown with kotulskite commonly contains microinclusions (1–3 μm) of Pd stannides: paolovite and atokite. Ore with 20–60% copper sulfides (0.2–6.0% Cu) contains 5.1–6.6 gpt PGE and up to 0.13–2.3 gpt Au. Pd minerals, arsenides and sulfoarsenides of Pt, Rh, Ir, Os, and Ru are identified as well. These are sperrylite, ruthenium platarsite, hollingworthite, and irarsite; silvery gold and paolovite have also been noted. All these minerals have been revealed in the massif for the first time. The paper also presents data on the compositions of 25 PGE minerals (PGM) from Kaalamo ores. 相似文献
14.
Precious-metal distribution and fluid-inclusion petrography of the Elatsite porphyry copper deposit,Bulgaria 总被引:4,自引:2,他引:2
The Elatsite porphyry copper deposit occurs in an island-arc setting hosted by Late Cretaceous monzonitic-monzodioritic porphyry stocks which were emplaced into Precambrian-Cambrian phyllites. Trace element data of the Late Cretaceous intrusive rocks suggest that they are I-type volcanic arc granitoids. Two main ore mineral assemblages are distinguished: (1) magnetite-bornite-chalcopyrite, and (2) chalcopyrite-pyrite. The first one is linked to potassic-propylitic, and the second to phyllic-argillic alteration. Minor ore minerals are hematite, molybdenite, sphalerite, pyrrhotite, marcasite, hessite, and solid solutions of linnaeite-siegenite-carrollite, tetrahedrite-tennantite, clausthalite-galena, gold-electrum and merenskyite-moncheite. Precious-metal contents are relatively high throughout the deposit but Au, Pd and Pt are concentrated more strongly in the magnetite-bornite-chalcopyrite assemblage. Average grades of Au, Ag, Pd and Pt calculated for the 0.33% Cu ore body are 0.96, 0.19, 0.007 and 0.002 g/t respectively. Analyses of flotation concentrates revealed 25.6% Cu, and Ag, Au, Pd and Pt contents of 33.0, 13.6, 0.72 and 0.15 g/t respectively. The copper mineralisation at Elatsite took place at pressures of 120 to 300 bar, corresponding to depths of formation of 1 to 3 km under hydrostatic conditions. The precious metals were probably transported jointly as chloride complexes in highly saline magmatic-hydrothermal solutions. The fluids had temperatures of 340 to >700 °C and salinities of 28 to 64% NaCl, and mixed with meteoric water. 相似文献
15.
Palladium, Platinum and Gold Concentrations in Fengshan Porphyry Cu–Mo Deposit, Hubei Province, China 总被引:1,自引:0,他引:1
Abstract: The Fengshan porphyry-skarn copper–molybdenum (Cu–Mo) deposit is located in the south-eastern Hubei Province in east China. Cu–Mo mineralization is hosted in the Fengshan granodiorite porphyry stock that intruded the Triassic Daye Formation carbonate rocks in the early Cretaceous (~140 Ma), as well as the contact zone between granodiorite porphyry stock and carbonate rocks, forming the porphyry-type and skarn-type association. The Fengshan granodiorite stock and the immediate country rocks are strongly fractured and intensely altered by hydrothermal fluids. In addition to intense skarn alteration, the prominent alteration types are potassic, phyllic, and propylitic, whereas argillation is less common. Mineralization occurs as veins, stock works, and disseminations, and the main ore minerals are chalcopyrite, pyrite, molybdenite, bornite, and magnetite. The contents of palladium, platinum and gold (Pd, Pt and Au) are determined in nine samples from fresh and mineralized granodiorite and different types of altered rocks. The results show that the Pd content is systematically higher than Pt, which is typical for porphyry ore deposits worldwide. The Pt content ranges from 0.037 to1.765 ppb, and the Pd content ranges between 0.165 and 17.979 ppb. Pd and Pt are more concentrated in porphyry mineralization than skarn mineralization, and have negative correlations with Au. The reconnaissance study presented here confirms the existence of Pd and Pt in the Fengshan porphyry-skarn Cu–Mo deposit. When compared with intracontinent and island arc geotectonic settings, the Pd, Pt, and Au contents in the Fengshan porphyry Cu–Mo deposit in the intracontinent is lower than the continental margin types and island are types. A combination of available data indicates that Pd and Pt were derived from oxidized alkaline magmas generated by the partial melting of an enriched mantle source. 相似文献
16.
New data on the composition, assemblages, and formation conditions of platinum-group minerals (PGM) identified in platinum-group
element (PGE) occurrences of the Monchetundra intrusion (2495 +- 13 to 2435 ± 11 Ma) are described. This intrusion is a part
of the Paleoproterozoic pluton of the Monche-Chuna-Volch’i and Losevy tundras located in the Pechenga-Imandra-Varzuga Rift
System. The rhythmically layered host rocks comprise multiple megarhythms juxtaposed to mylonite zones and magmatic breccia
and injected by younger intrusive rocks in the process of intense and long magmatic and fluid activity in the Monchetundra
Fault Zone.
The primary PGM and later assemblages that formed as a result of replacement of the former have been identified in low-sulfide
PGE occurrences. More than 50 minerals and unnamed PGE phases including alloys, Pt and Pd sulfides and bismuthotellurides,
PGE sulfarsenides, and minerals of the Pd-As-Sb, Pd-Ni-As, and Pd-Ag-Te systems have been established. The unnamed PGE phases—Ni6Pd2As3, Pd6AgTe4, Cu3Pt, Pd2NiTe2, and (Pd, Cu)9Pb(Te, S)4—are described. The primary PGM were altered due to the effect of several mineral-forming processes that resulted in the formation
of micro- and nanograins of Pt and Pd alloys, sulfides, and oxides, as well as in the complex distribution of PGE, Au, and
Ag mineral assemblages. New types of complex Pt and Pd oxides with variable Cu and Fe contents were identified in the altered
ores. Pt and Pd oxides as products of replacement of secondary Pt-Pd-Cu-Fe alloys occur as zonal and fibrous nanoscale Pt-Pd-Cu-Fe-(±S)-O
aggregates. 相似文献
17.
Mustapha El Ghorfi Thomas Oberthür Frank Melcher Volker Lüders Abdelmajid El Boukhari Lhou Maacha Rachid Ziadi Hssain Baoutoul 《Mineralium Deposita》2006,41(6):549-564
The structurally controlled Au–Pd mineralization at Bleïda Far West occurs in a volcano-sedimentary rock sequence in altered amphibolites and chlorite schists of the Neoproterozoic Bou Azzer–El Graara inlier. The Au–Pd mineralization is virtually sulfide-free; instead, gold is associated with hematite, barite, quartz, and calcite. The gold grains are silver- and palladium-bearing (up to 19 wt% Ag and 6.3 wt% Pd) and are intergrown with a distinct suite of mainly Pd-dominated platinum group minerals, namely mertieite-I/isomertieite, merenskyite, keithconnite, kotulskite, palladseite, and sperrylite, defining a Au–Pd–As–Sb–Se–Te chemical signature. Stable isotope and fluid inclusion studies indicate a wide range of fluid compositions with a prominent saline component. In conjunction with the mineral association, oxidizing fluids are indicated, and Au and PGE transport and deposition likely took place by chloride complexes in the epithermal range, at elevated f O2 and/or low pH. It is still speculative whether the mineralization is late Pan-African (~600–550 Ma) in age, or connected with the Variscan orogeny (~330–300 Ma), or related to some other hydrothermal event. Common to all Au–Pd mineralizations worldwide (Brazil, Australia, UK), including Bleïda Far West, is their formation in the epithermal (<300°C) range; deposition mainly in brittle structures; sulfide-poor mineral assemblages comprising hematite, sulfate minerals, and selenides; and metal transport by, and deposition from, oxidized, chloride-rich fluids. These deposits are further characterized by noble metal abundances in the order Au>Pd>Pt and the chemical signature Au–Pd–Se–Te (±As, Sb, Bi). As such, the Au–Pd association represents a discrete style of gold mineralization distinct from other classes of gold deposits. 相似文献
18.
辽河油田稠油中贵金属分布和赋存状态研究 总被引:1,自引:0,他引:1
以辽河油田稠油为研究对象,通过原子吸收光谱、实沸点蒸馏等手段,研究了辽河油田稠油中Au、Ag、Pt和Pb等贵金属在不同馏分中的分布特征.结果表明,经过实沸点蒸馏后,贵金属不同沸程温度的原油馏分中含量和分布存在很大差异,Au、Ag、Pt、Pd主要集中在渣油馏分中,在沸点》508℃的渣油馏分中Au、Ag、Pt、Pd的比例分别是93.4%、76.9%、73.4%和68.0%;采用选择性萃取的方法对金在稠油中的存在形态的初步研究发现,金在稠油中主要以有机配合物和少量无机配合物形式存在. 相似文献
19.
电子探针测年方法应用于晶质铀矿的成因类型探讨 总被引:7,自引:4,他引:3
电子探针Th-U-Pb测年因其高分辨率与高精度的优势,在独居石、锆石等定年矿物中得到了推广,但在Th、U、Pb含量高的晶质铀矿、沥青铀矿等矿物中则应用较少。本文在铁矿床变质岩绿泥石、阳起石黑云母蚀变岩首次发现U含量高的晶质铀矿,基于此,结合该铁矿床地区的地质背景,利用偏光显微镜与电子探针等分析测试手段,将镜下蚀变现象、年龄计算与其他相关元素分析相结合,重点对晶质铀矿的成矿年龄及成矿规律进行探讨。研究发现:通过镜下观察判断,晶质铀矿的成因类型与澳大利亚著名的变质型铀矿相似,均为古老的变质型,且周围的脉石矿物均为绿泥石,绿泥石皆由黑云母退变质而成,铀矿的赋存位置显示其与黑云母、绿泥石之间有紧密联系,其成矿年龄与黑云母、绿泥石形成年龄息息相关。继而根据电子探针数据计算成矿年龄,判断成矿期次,得出主要成矿期在(1654±17)Ma~(1805±17)Ma,为中元古代中期,且主要成矿期与热液蚀变作用黑云母化有关,后期活化富集时期在(657±17)Ma~(807±17)Ma,为新元古代南华纪时期,此阶段是热液侵入、绿泥石化广泛发育的时期;选取较大颗粒对晶质铀矿的环带年龄进行计算,从年龄分布上证实后期有强烈的流体活动的发生,且主要与绿泥石化相关。另外,对比变质型与沉积型铀矿中Y2O3与UO2含量发现,两者之间存在负相关关系,此关系对判断铀矿成因即是否为变质型或沉积型可能有指示意义,但缺乏大量的数据佐证,需进一步研究。 相似文献
20.
Rhenium–osmium ages were determined for two molybdenite samples and a Pb–Pb age was derived from bornite–chalcopyrite–magnetite at the Salobo iron oxide copper–gold deposit to determine the timing of mineralization and its relation to the nearby Old Salobo Granite. Rhenium–osmium dating of molybdenite spatially associated with copper sulfide minerals yields ages with weighted means of 2576±8 and 2562±8 Ma. Removing the error multiplier introduced by the decay constant uncertainty, appropriate for comparing ages from the same isotopic system, these data convincingly argue for two temporally separated pulses of molybdenite deposition at 2576.1±1.4 Ma (n=2) and 2561.7±3.1 Ma (n=3). The 2576±8 Ma age coincides with a previously published U–Pb age of 2573±2 Ma for the Old Salobo Granite, suggesting that main stage ore formation may have been contemporaneous with granite magmatism. The slightly younger 2562 Ma age most likely represents new molybdenite precipitation associated with the development or reactivation of local shear zones. Lead–lead stepwise leaching of copper sulfide minerals yields a less precise isochron age of 2579±71 Ma, and supports an Archean age for the Salobo ores. This is the first documentation of an Archean iron oxide copper–gold deposit, and the Re–Os and Pb–Pb geochronology herein support 2580–2550 Ma estimates for basement reactivation and regional granite magmatism associated with the development of brittle–ductile shear zones. 相似文献