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1.
金川铜镍硫化物矿床铂族元素的赋存状态及分布规律 总被引:17,自引:3,他引:14
金川铜硫化物矿床铂族元素球粒陨石标准化型式属于Pt-Pd配分类型,Pt、pd〉Os、Ir、Ru、Rh,存在3种不同形式的图形;PGE(铂族元素)在熔离和深熔--贯入型岩矿体中,PGE含量从非含矿岩石→SN-B→SN-A2→SN-A1依次增加,显示与金属硫化物含量具有正消长关系;矿石中80%以上的铂和70T以上的钯呈矿物相存在;PGE富集体主要分布在富矿体膨大处的中、下部。 相似文献
2.
红石砬铂矿地球化学异常组分简单,仅发育Pt和Pd的强异常,部分伴生Au异常,不伴生Cr、Co、Cu、Ni、V、As、Sb、Ag、Pb等元素异常。岩石、土壤、水系沉积物中Pt、Pd的分布和异常模式与铂族矿化特征、矿体剥蚀程度及其表生地球化学行为等有关。矿体出露地表时,Pt、Pd呈强异常分布,异常的w(Pt)/w(Pd)比值与矿石中w(Pt)/w(Pd)比率基本一致;隐伏矿体上方,Pd有明显的浓集,w(Pt)/w(Pd)比值小于地表矿体。表生环境中,Pt、Pd可以呈矿物碎屑、可溶态等多种形式迁移,在疏松沉积物中形成异常。因此,以Pt、Pd作为直接指示元素,进行地球化学勘查,可以发现这种类型的铂族矿床。 相似文献
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峨眉山玄武岩的铂族元素地球化学特征 总被引:38,自引:4,他引:34
采用镍锍试金预处理中子活化分析方法,系统地测定了峨眉山玄武岩的铂族元素含量。14个样品的平均值为:Os=0.39ng/g,Ir=0.0698ng/g,Ru=0.49ng/g,Rh=0.25ng/g,Pt=7.71ng/g,Pd=5.48ng/g。相对于原始上地幔,峨眉山玄武岩的铂族元素分异明显,Os、Ir、Ru、Rh亏损,Pt、Pd富集。(Pt+Pd)/(Os+Ir+Ru)比值(平均13.96)和Pd/Ir比值(平均78.5)显著高于原始上地幔、地幔捕虏体、阿尔卑斯型橄榄岩及科马提岩。铂族元素配分模式为铂钯富集型。以上这些特征表明其原始岩浆为上地幔低程度部分熔融形成的玄武岩浆。 相似文献
5.
蚀变超基性岩金(镍)矿床中的贵金属元素──以云南墨江金矿和陕西煎茶岭金矿为例 总被引:9,自引:0,他引:9
云南墨江金矿和陕西煎茶岭金矿中Ag、Au和PGE(铂族元素)的丰度和共生状况如下:(1)两矿床中的Ag-Au关系呈三种情况:硅质岩型矿石和其他类型低品位金矿石中Ag-Au基本上不具相关关系;石英脉型矿石中Ag-Au呈明显的正相关关系;氧化矿石中Ag-Au呈负相关关系。(2)所有样品中的PGE均低于71×10(-6),其PGE的特征是Pt≥Pd和Ru>Os、Ir、Rh。(3)这些样品的地幔标准化PGE分布模式是以Rh为峰的上凸曲线,而墨江样品又具Ir的负异常。与一般超基性岩的情况不同,这些样品的模式曲线中Pd-Au部分呈陡弯折,它表明矿化元素金可能主要由区域成矿流体提供。 相似文献
6.
该铂-金砂矿产于超基性岩体山前谷地的第四纪冲积-洪积层中。在60年代,前人曾对该铂-金砂矿作过初步评价,但对其中的铂族元素矿物未进行过矿物学研究。笔者于1992年夏对该砂矿作了调研,并对吕明鸿工程师所提供的该砂矿的铂族矿物样品进行了物理光学性质研究及电子探针和X射线分析。业已查明,它们主要是铱锇矿、钉铱锇矿、锇铱矿、自然锇、等轴铁铂矿;矿物共生组合为自然金+上述铂族矿物+自然银+铬尖晶石+铬铁矿+磁铁矿+钛铁矿+辰砂。这表明,该铂-金砂矿的物质来源为含铬超基性岩。 相似文献
7.
试论铂族元素地球化学示踪体系 总被引:14,自引:1,他引:14
试论铂族元素地球化学示踪体系李胜荣,高振敏,陈南生(中国科学院地球化学研究所,贵阳550002)关键词铂族元素,地球化学示踪,典型配分型式稀土元素作为地球化学示踪剂已为人们所熟知。Ru、Rh、Pd、Os、Ir、Pt是一组化学和物理性质颇为相似的元素,... 相似文献
8.
铂族元素矿物共生组合(英文) 总被引:1,自引:2,他引:1
由于铂族元素能有效地降低汽车尾气的污染 ,其需求量日益增加 ,对铂族元素矿床的寻找已是当务之急。着重从矿物矿床学角度对铂族元素的矿物共生特点进行了探讨。铂族元素可呈独立矿床产出 ,主要产于基性超基性层状侵入体、蛇绿岩套及阿拉斯加式侵入体中。铂族元素也伴生于铜镍矿床中 ,该类铜镍矿床主要与苏长岩侵入体、溢流玄武岩及科马提岩有关。产于基性超基性层状侵入体中的铂族矿物有铂钯硫化物、铂铁合金、钌硫化物、铑硫化物、铂钯碲化物、钯砷化物及钯的合金。这些铂族矿物可与硫化物矿物共生 ,也可与硅酸盐矿物共生 ,还可与铬铁矿及其他氧化物矿物共生。产于蛇绿岩套中的铂族矿物主要是钌铱锇的矿物 ,而铂钯铑的矿物则较少出现 ,这些铂族矿物可呈合金、硫化物、硫砷化物以及砷化物 4种形式出现。产于阿拉斯加式侵入体中的铂族矿物主要有铂铁合金、锑铂矿、硫铂矿、砷铂矿、硫锇矿及马兰矿等少数几种 ,其中铂铁合金与铬铁矿及与其同时结晶的高温硅酸盐矿物共生 ,而其他的铂族矿物则与后来的变质作用及蛇纹岩化作用中形成的多金属硫化物及砷化物共生。产于铜镍矿床中的铂族矿物主要是铂和钯的矿物。产于基性超基性层状侵入体、蛇绿岩套及阿拉斯加式侵入体中的铂族矿物的共同特点是它们均与铬铁矿? 相似文献
9.
锍试金富集贵金属元素:I.等离子体质谱法测定地质样品中痕量铂族元素 总被引:30,自引:16,他引:30
纯化了捕集剂,用锍试金结合Te共沉淀富集,等离子体质谱法测定了地质样品中的铂族元素,全流程铂族元素回收率大于94%,一次熔样可同时测定了6个铂族元素,按20g取样计算,方法检出限(ng/g)分别为0.024,Ru,0.013,Rh,0.20,Pd,0.033,Os0.39,Ir0.12Pt;对标准GPt-6平行测定5次,铂族元素相对标准偏差为1%(Os)~8%(Pt)对不同类型标样进行测定,测得结 相似文献
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11.
The paper presents concentrations of the platinum-group and chalcophile elements in the base metal sulfides (BMS) from the Jinchuan Ni–Cu sulfide deposit determined by laser ablation-inductively coupled plasma-mass spectrometry. Mass balance calculations reveal that pentlandite hosts a large proportion of Co, Ni and Pd (> 65%), and that pentlandite and pyrrhotite accommodate significant proportions of Re, Os, Ru, Rh, and Ag (~ 35–90%), whereas chalcopyrite contains a small amount of Ag (~ 10%) but negligible platinum-group elements. Iridium and Pt are not concentrated in the BMS and mostly occur in As-rich platinum-group minerals. The enrichments of Co, Ni, Re, Os, Ru, and Rh in pentlandite and pyrrhotite, and Cu in chalcopyrite are consistent with the fractionation of sulfide liquid and exsolution of pentlandite and pyrrhotite from the mono-sulfide solid solution (MSS). The Ir-bearing minerals exsolved from the MSS, depleting pentlandite and pyrrhotite in Ir, whereas sperrylite exsolved from the residual sulfide liquid on cooling. Diffusion of Pd from residual sulfide liquid into pentlandite during its exsolution from the MSS and crystallization of Pt-bearing minerals in the residual sulfide liquid resulted in the enrichment of Pd in pentlandite and decoupling between Pd and Pt in the Jinchuan net-textured and massive ores. 相似文献
12.
来自蛇绿岩地幔的硫(砷)化物矿物组合 总被引:1,自引:0,他引:1
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。 相似文献
13.
N. M. Chernyshov 《Geology of Ore Deposits》2009,51(8):684-697
High-carbonaceous stratified formations and related metasomatic rocks of global abundance are among highly promising sources of gold and platinum-group metals (PGMs) in the 21st century. The Au-PGM mineralization of the black-shale type hosted in the Early Karelian Kursk and Oskol groups in central Russia is characterized by complex multicomponent and polymineralic composition (more than 60 ore minerals, including more than 20 Au and PGM phases) and diverse speciation of noble metals in form of (1) native elements (gold, palladium, platinum, osmium, silver); (2) metallic solid solutions and intermetallic compounds (Pt-bearing palladium, Fe-bearing platinum, gold-platinum-palladium, osmiridium, rutheniridosmin, platiridosmin, platosmiridium, Hg-Te-Ag-bearing gold, gold-silver amalgam, arquerite, palladium stannide (unnamed mineral), platinum-palladium-gold-silver-tin); (3) PGM, Au, and Ag sulfoarsenides, tellurides, antimonides, selenides, and sulfosalts (sperrylite, irarsite, hessite, Pd and Pt selenide (unnamed mineral)), testibiopalladinite, Pd antimonide (unnamed mineral), etc.; and (4) impurities in ore-forming sulfides, sulfoarsenides, tellurides, antimonides, and selenides. The chemical analyses of PGM and Au minerals are presented, and their morphology and microstructure are considered. 相似文献
14.
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
15.
Solid inclusions in chrome-spinels and platinum group element concentrations from the hochgrössen and kraubath ultramafic massifs (Austria) 总被引:1,自引:0,他引:1
O. A. R. Thalhammer W. Prochaska H. W. Mühlhans 《Contributions to Mineralogy and Petrology》1990,105(1):66-80
A great variety of platinum group mineral, sulfide and silicate inclusions in chrome spinel from Hochgrössen and Kraubath ultramafic massifs, and platinum group element contents of three different rock types have been investigated. Both ultramafic massifs are tectonically isolated bodies, variably serpentinized and metamorphosed (greenschist to lower amphibolite facies), and show ophiolitic geochemical affinities. The chromite from massive chromitites and disseminated in serpentinized dunites and serpentinites, exhibits compositional zonation as the result of alteration during serpentinization and metamorphism. Three distinctive alteration stages are indicated in the chrome-spinels from the Hochgrössen, whereas alteration is less significant in chromites from Kraubath: The core of chrome spinel represents the least altered part, surrounded by an inner rim characterized by slight compositional differences in Cr, Mn, Fe2+ and Al with respect to the core. The outer rim is formed by ferritchromite with a sharp boundary to the inner rim and shows a significant decrease of Al, Mg, Cr and increase of Fe2+, Fe3+ and Ni compared to the core. Two different groups of inclusions in chrome-spinel are present: the first group occurs within the chromite core, and comprises olivine, orthopyroxene, amphibole, sulfides and platinum-group minerals, i.e. dominated by Ru-Os-Ir-sulfides. The second group is formed by chlorite, serpentine, galena, pyrite, arsenopyrite, Pt-Pd-Rh-dominated sulfarsenides and sperrylite. In particular the abundance of Pt-Pd-Rh-sulfarsenides and arsenides is typical of both ultramafic massifs and is very unusual for chromitites from ophiolites. Morphology, paragenesis and chemical composition indicate a different origin for these two groups of inclusions. The first group is intimately related to the crystallisation of the chromite host. The second group of inclusions clearly displays a secondary formation during serpentinization and metamorphism, closely related to the alteration of chrome-spinel and the development of ferritchromite. The distribution patterns of the platinum group elements from massive chromitites, disseminated chrome-spinel bearing serpentinites and serpentinites exhibit variable enrichment of Rh, Pt and Pd, Rh, Pt for the Hochgrössen and Kraubath massifs, respectively. These results are in accordance with the occurrence and distribution of platinum-group mineral phases. A remobilisation of Pt, Pd, and Rh, together with Ni, Cu and possibly Fe as bisulfide and/or hydroxide complexes and deposition of metals by the reaction of the metal bearing hydrothermal fluid with chromite is proposed. 相似文献
16.
Inga Osbahr Reiner Klemd Thomas Oberthür Helene Brätz Robert Schouwstra 《Mineralium Deposita》2013,48(2):211-232
Base-metal sulfides in magmatic Ni-Cu-PGE deposits are important carriers of platinum-group elements (PGE). The distribution and concentrations of PGE in pentlandite, pyrrhotite, chalcopyrite, and pyrite were determined in samples from the mineralized portion of four Merensky Reef intersections from the eastern and western Bushveld Complex. Electron microprobe analysis was used for major elements, and in situ laser ablation inductively-coupled plasma mass spectrometry (LA-ICP-MS) for trace elements (PGE, Ag, and Au). Whole rock trace element analyses were performed on representative samples to obtain mineralogical balances. In Merensky Reef samples from the western Bushveld, both Pt and Pd are mainly concentrated in the upper chromitite stringer and its immediate vicinity. Samples from the eastern Bushveld reveal more complex distribution patterns. In situ LA-ICP-MS analyses of PGE in sulfides reveal that pentlandite carries distinctly elevated PGE contents, whereas pyrrhotite and chalcopyrite only contain very low PGE concentrations. Pentlandite is the principal host of Pd and Rh in the ores. Palladium and Rh concentrations in pentlandite reach up to 700 and 130 ppm, respectively, in the samples from the eastern Bushveld, and up to 1,750 ppm Pd and up to 1,000 ppm Rh in samples from the western Bushveld. Only traces of Pt are present in the base-metal sulfides (BMS). Pyrrhotite contains significant though generally low amounts of Ru, Os, and Ir, but hardly any Pd or Rh. Chalcopyrite contains most of the Ag but carries only extremely low PGE concentrations. Mass balance calculations performed on the Merensky Reef samples reveal that in general, pentlandite in the feldspathic pyroxenite and the pegmatoidal feldspathic pyroxenite hosts up to 100 % of the Pd and Rh and smaller amounts (10–40 %) of the Os, Ir, and Ru. Chalcopyrite and pyrrhotite usually contain less than 10 % of the whole rock PGE. The remaining PGE concentrations, and especially most of the Pt (up to 100 %), are present in the form of discrete platinum-group minerals such as cooperite/braggite, sperrylite, moncheite, and isoferroplatinum. Distribution patterns of whole rock Cu, Ni, and S versus whole rock Pd and Pt show commonly distinct offsets. The general sequence of “offset patterns” of PGE and BMS maxima, in the order from bottom to top, is Pd in pentlandite?→?Pd in whole rock?→?(Cu, Ni, and S). The relationship is not that straightforward in general; some of the reef sequences studied only partially show similar trends or are more complex. In general, however, the highest Pd concentrations in pentlandite appear to be related to the earliest, volumetrically rather small sulfide liquids at the base of the Merensky Reef sequence. A possible explanation for the offset patterns may be Rayleigh fractionation. 相似文献
17.
A.V. Kutyrev E.G. Sidorov A.V. Antonov V.M. Chubarov 《Russian Geology and Geophysics》2018,59(8):935-944
In the alluvial deposits of the Prizhlimny Creek (southern part of the Koryak Highland), grains of platinum-group minerals are found along with gold. We have established that the grains are native platinum (Pt, Fe) containing Cu (up to 5 wt.%), Os (up to 8 wt.%), and Rh (up to 2 wt.%). Inclusions in the platinum are native osmium (the content of Ir impurity reaches 12 wt.%, the average content being 0.2–4 wt.%), an unnamed intermetallic compound of composition PtRh, sulfides and arsenides of PGE (cooperite, laurite, malanite, cuproiridsite, cuprorhodsite, sperrylite, hollingworthite, unnamed compounds PdS, (Ir,Ru)S2, (Ir,Pt)S2, Cu, and Fe (bornite, chalcopyrite), chromite, and Cr-magnetite. Replacement of native-osmium crystals by compound IrO2 is described. It has been established that this compound formed during oxidation accompanied by the replacement of isoferroplatinum by native platinum. The data obtained agree with the results of study of platinum-group mineral assemblages from placers localized in weakly eroded Ural–Alaskan-type massifs whose apical parts formed under high oxygen activity conditions. Clinopyroxenites of the Prizhimny massif are considered to be the potential source of PGE. 相似文献
18.
The contents of the platinum-group elements (PGEs: Os, Ir, Ru, Rh, Pt, Pd) in the Abulangdang ultramafic intrusion have been
determined using ICP-MS after nickel sulfide fire assay preconcentration. Different samples show significant differences in
absolute PGE abundance. They display a pronounced negative incline in mantle-normalized patterns which are characterized by
strong enrichment in IPGEs (Os, Ir, Ru) and depleting to slight enrichment in PPGEs (Rh, Pt, Pd). The characteristics of PGE
distribution in the Abulangdang rocks are due to the combined action of sulfide and non-sulfide (spinel/chromite or alloy
or micro-granular aggregation of metals). In comparison with the mafic-ultramafic rocks which host Ni-Cu-PGE deposits in the
Emeishan Large Igneous Province (ELIP), it is assumed that the Abulangdang ultramafic intrusion may be the product of early-stage
magma activity in the ELIP. 相似文献
19.
Summary ?We report, for the first time, the occurrence of five palladium-rich, one palladium bearing and two gold-silver minerals
from podiform chromitites in the Eastern Alps. Minerals identified include braggite, keithconnite, stibiopalladinite, potarite,
mertieite II, Pd-bearing Pt-Fe alloy, native gold and Ag-Au alloy. They occur in heavy mineral concentrates produced from
two massive podiform chromitite samples (unaltered and highly altered) of the Kraubath ultramafic massif, Styria, Austria.
Distribution patterns of platinum-group elements (PGE) in these chromitites show considerable differences in the behaviour
of the less refractory PGE (PPGE-group: Rh, Pt, Pd) compared to the refractory PGE (IPGE-group: Os, Ir, Ru). PPGE are more
enriched in chromitite showing pronounced alteration features. The unaltered chromitite displays a negatively sloped chondrite-normalised
PGE pattern similar to typical ophiolitic-podiform chromitite.
Except for the Pd- and Au-Ag minerals that are generally rare in ophiolites, about 20 other platinum-group minerals (PGM)
have been discovered. They include PGE-sulphides (laurite, erlichmanite, kashinite, bowieite, cuproiridsite, cuprorhodsite,
unnamed Ir-rich variety of ferrorhodsite, unnamed Ni-Fe-Cu-Rh- and Ni-Fe-Cu-Ir-Rh monosulphides), PGE alloys (Pt-Fe, Ir-Os,
Os-Ir and Ru-Os-Ir), PGE-sulpharsenides (irarsite, hollingworthite, platarsite, ruarsite and a number of intermediate species),
sperrylite and a Ru-rich oxide (?). Three PGM assemblages have been recognised and attributed to different processes ranging
from magmatic to hydrothermal and weathering-related.
Pd-rich minerals are characteristic of both chromitite types, although their chemistry and relative proportions vary considerably.
Keithconnite, braggite and Pd-bearing ferroan platinum, together with a number of PGE-sulphides (mainly laurite-erlichmanite)
and alloys, are typical only of the unaltered podiform chromitite (assemblage I). Euhedral mono- and polyphase PGM grains
in the submicron to 100 μm range show features of primary magmatic assemblages. The diversity of PGM in these assemblages
is unusual for ophiolitic environments. In assemblage II, laurite-erlichmanite is intergrown with and overgrown by PGE-sulpharsenides;
other minerals of assemblage I are missing. Potarite, stibiopalladinite, mertieite II, native gold and Ag-Au alloys, as well
as PGE-sulpharsenides, sperrylite and base metal arsenides and sulphides are characteristic for the highly altered chromitite
(assemblage III). They occur either interstitial to chromite in association with metamorphic silicates, in chromite rims or
along cracks, and are thus interpreted as having formed by remobilization of PGE by hydrothermal processes during polyphase
regional metamorphism.
Received August 3, 2000;/revised version accepted December 28, 2000 相似文献