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四川丹巴杨柳坪矿床是峨眉大火成岩省典型铜镍硫化物矿床,此类矿床中蕴藏了丰富的铂族资源。岩矿石光片的扫描电镜与电子探针分析表明,四川丹巴杨柳坪铜镍硫化物矿床中Pt、Pd以独立矿物为主,少量铱族矿物具有成因指示意义,极少量Pt、Pd元素呈类质同象形式赋存于磁黄铁矿、黄铜矿中。Pt主要以独立矿物砷铂矿的形式存在,矿物粒径1~60μm,呈半自形-自形,主要被磁黄铁矿包裹,部分穿切磁黄铁矿、黄铜矿,少量被橄榄石与菱镁矿包裹。Pd以碲锑钯矿的形式存在,矿物自形程度较差,大量赋存于黄铜矿、磁黄铁矿等金属硫化物的裂隙,部分被黄铜矿包裹,少量形成于热液阶段的碲锑钯矿与辉砷钴矿紧密共生充填于裂隙中。铱族矿物呈半自形-自形与高温热液矿物辉砷钴矿紧密共生。 相似文献
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金川铜镍硫化物矿床是我国最主要的铂族元素(PGE)资源产地,其矿石受热液蚀变作用影响明显,并产出多种铂族矿物(PGM)。岩浆演化和热液蚀变过程中PGE的迁移富集机制和PGM的成因,一直是研究PGE地球化学行为非常关注的问题。本文对金川铜镍硫化物矿床中PGM的研究发现,其主要类型包括含PGE的硫砷化物(硫砷铱矿)和砷化物(砷铂矿),Pd的铋化物、碲化物和硒化物,以及少量其他铂族矿物。其中,硫砷铱矿可包裹于各种贱金属硫化物(镍黄铁矿、磁黄铁矿和黄铜矿)中,表明硫砷铱矿可能结晶于早期的含As硫化物熔体,随后被包裹于硫化物熔体冷凝分异产生的单硫化物固溶体(MSS)和中间硫化物固溶体(ISS)中。硫化物熔体中的As可能主要通过地壳混染作用加入幔源岩浆。大量铋钯矿(PdBi)呈微细乳滴状包裹于黄铜矿中,为晚期ISS冷凝形成黄铜矿过程中出溶的产物。少量铋钯矿(PdBi_2)呈不规则状充填于矿物裂隙,与次生磁铁矿脉紧密共生,并随矿石的蚀变程度增加,铋钯矿的化学成分由PdBi逐渐向PdBi_2转变,表明这部分铋钯矿为后期热液蚀变产物。铋碲钯矿和钯的硒化物则主要产出于镍黄铁矿裂隙且与次生磁铁矿紧密共生,指示明显的热液成因。钯的硒化物的出现表明,岩浆期后酸性、高盐度、高氧逸度的富Cl~-流体对金川铜镍硫化物矿床中Pd的迁移和富集起到了关键控制作用。 相似文献
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砷铂矿(Sperrylite)PtAs-2系一种稀少的铂族元素矿物.主要产于与基性岩-超基性岩有关的铜镍硫化物矿床中.砷铂矿在世界上发现的地区尚不多,已知的产地有加拿大的肖德别里铜镍硫化物矿床、南非铂矿以及苏联等几个地区.我国至今尚未报导过砷铂矿的文章.砷铂矿为一种化学成份简单且很稳定的铂砷化物.主要成份是Pt、As.其理论值是Pt为56.58%,As为43.42%,且经常合有少量的Fe,除此之外有些样品中含有Rh、Pd、Cu、Sb等微量元素.砷铂矿主要产于富含铂族元素的铜镍硫化物矿床中.本文 相似文献
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利用扫描电镜和能谱技术研究四川会理铂钯矿床中的铂族矿物特征及铂族元素赋存状态 总被引:2,自引:2,他引:0
四川会理铂钯矿床是独立的铂族元素矿床,局部地段的铂钯含量已达工业品位,当前迫切需要详细掌握铂族矿物和铂族元素赋存状态。由于原矿铂族元素品位总体较低,采用化学分析方法分析测试只能间接研究铂族元素的赋存状态,所得结论并不全面。本文结合化学分析方法的测试结果,利用扫描电镜及能谱获得了会理铂钯矿床铂族矿物的精细特征。结果表明:该矿床中铂族元素主要是铂和钯;铑、铱、钌、锇含量很低,且未发现这四种元素的独立矿物。铂和钯有单质和与砷、碲、锑、铋形成的化合物;独立铂族矿物有17种,主要是自然铂、砷铂矿、砷钯铂矿或砷铂钯矿、钯铂铜矿或铂钯铜矿,其次可见少量承铂矿及其他铂族矿物。铂族矿物嵌布状态有两种——被包裹和粒间,被包裹占52.39%,粒间占47.62%。绝大多数铂族矿物呈他形粒状,只有少量砷铂矿晶形较好。铂族矿物粒径范围为1.36~32.7μm,大小差异大。有的铂族矿物表面具微孔结构,有的呈葡萄状,有的可见环边现象。接触方式以曲线接触为主,直线接触次之。这些信息为该矿床矿石选冶和铂族资源评价提供了科学依据。 相似文献
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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
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金川岩浆铜镍(铂)硫化物矿床是我国最主要的铂族等战略性关键金属宝库。金川矿床中铂族金属的富集过程和富集机制还存在很多争论。本文通过详细的矿物学及矿床学研究,厘定了金川矿床成矿阶段。成矿阶段可划分为硫化物矿浆结晶阶段、挥发分流体作用阶段及热液改造阶段。其中硫化物矿浆结晶阶段的主要矿物组合为镍黄铁矿(Pn- a)- 磁黄铁矿(Po- a)- 黄铜矿(Ccp- a);挥发分流体作用阶段的主要矿物组合为镍黄铁矿(Pn- b)- 磁黄铁矿(Po- b)- 黄铜矿(Ccp- b)- 黄铁矿(Py- Ⅰ)- 磁铁矿(Mag- Ⅰ)- 菱铁矿- 叶蛇纹石- 磷灰石- 铬铁矿- 白云石- 方解石(Cal- Ⅰ)- 金云母。热液改造阶段的矿物组合为透闪石- 绿泥石- 蛇纹石- 方解石(Cal- Ⅱ)- 磁铁矿(Mag- Ⅱ)。高倍电子探针镜下发现,金川矿床铂族矿物与磁铁矿(Mag- Ⅰ)、黄铁矿(Py- Ⅰ)、铬铁矿、磷灰石、黄铜矿、磁黄铁矿、镍黄铁矿及菱铁矿等共生。金川铜镍硫化物矿床中铂族元素(PGM)矿物主要包括硫砷铱矿(IrAsS)、钯的铋化物、碲化物和硒化物、钯的金属互化物(PdAu2)、砷铂矿(PtAs2)、铂单质以及铂的金属合金(Pt- Fe)。其中大量的PGM分布于镍黄铁矿的裂隙中,或产于镍黄铁矿、磁黄铁矿及蛇纹石裂隙中。与磁铁矿、菱铁矿、铬铁矿、黄铜矿、磷灰石以及叶蛇纹石等矿物共生,指示PGE富集与氧化性流体加入密切相关。金川矿石镍黄铁矿(Pn- b)、磁黄铁矿(Po- b)、黄铜矿(Ccp- b)、黄铁矿(Py- Ⅰ)、磁铁矿(Mag- Ⅰ)以及菱铁矿中高Co含量,表明流体在Co的超常富集过程中也起到了决定性作用。金川矿石中大量碳酸盐矿物、叶蛇纹石、金云母、磁铁矿、黄铁矿、铬铁矿以及富Cl磷灰石的出现;S、Mg元素呈网脉状分布于蚀变橄榄石和硫化物中,推测流体组分可能是一种富C富Cl的富含挥发分的高氧逸度流体。金川铬铁矿、磁铁矿(Ⅰ)、菱铁矿等矿物中高Ti、高Nb含量和高Nb/Ta比值,暗示此流体可能是一种高温的超临界流体。以上特征综合表明该特征流体对金川铜镍硫化物矿床中铂族元素等关键金属的超常富集起到了关键控制作用。当挥发分流体与残余硫化物矿浆相互作用及改造先存硫化物及橄榄石时,不仅会促使Os、Ir、Ru、Rh、Pt、Pd进一步活化、富集,还会导致流体中PGE强烈富集,使得流体中的Pd、Se、Te、Bi、Pt含量不断提高,最终形成大量的PGM。综上所述,本文认为在岩浆演化晚期可能存在一种高氧逸度的富Cl富C的深源流体注入岩浆房,该深源挥发分流体对PGE及Co的迁移和超常富集起到了关键控制作用。 相似文献
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利用扫描电镜-电子探针研究四川杨柳坪镍铜硫化物矿床铂钯的赋存状态及沉淀机制 总被引:2,自引:2,他引:0
本文利用电子探针和配备能谱分析功能的扫描电镜对四川杨柳坪镍-铜硫化物矿床中铂钯的赋存状态进行了研究。结果表明,铂以独立矿物相砷铂矿和自然铂存在;钯以碲化物、碲铋化物、碲锑化物、锑化物及自然钯独立矿物相存在,也以类质同象形式分布在碲镍矿中(钯含量约10%),另外还以锑铋钯碲矿、六方锑碲钯矿、碲钯矿独立矿物相存,并以类质同象形式分布在Vavrinite(钯含量5%)和砷铂矿(钯含量1%~5%)中。杨柳坪矿床中铂钯元素沉淀与贱金属矿物(BMS)及晚期热液蚀变矿物蛇纹石、方解石密切相关,其沉淀经历了3个阶段:1早期高温阶段(1200~900℃),铂钯元素沉淀并包裹在BMS中;2中期中高温阶段(650~250℃),分离结晶作用使铂钯元素沉淀并分布BMS矿物的边部,同时该阶段热液来源的铂钯元素沉淀于BMS粒间;3晚期热液蚀变阶段(500~300℃),热液蚀变作用引起铂钯元素沉淀在蚀变矿物中或嵌布在BMS裂隙。本文研究成果为认识该矿床及同类型镍-铜硫化物矿床的铂钯成矿过程提供了新的依据。 相似文献
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喀拉通克铜镍硫化矿区二、三号矿床的两个岩体为隐伏的中-基性岩体,受北西向断裂的控制,侵位于石炭统南明水组上段之下部地层中,为岩浆熔离型铜镍硫化矿床。矿物成分以磁黄铁矿、镍黄铁矿、黄铜矿为主。有用元素除铜、镍外,尚伴生有金、银、铂、色、钴、硫可综合利用。它国内外同类型矿床相比,具有成岩、成矿时代新,岩体基性程度低、铜大于镍等特点,因而又具有新的地质找矿意义。 相似文献
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云南牟定安益矿床为一处铂族金属与钛磁铁矿共同产出的大型钛磁铁矿铂族金属矿床。目前对该矿床中铂族元素的赋存状态研究甚少。结合野外宏观地质特征和室内岩矿鉴定,笔者利用TIMA和LA-ICP-MS-Mapping分析方法,对安益矿床中铂族金属矿物学特征进行研究,发现安益矿床中的铂族元素(PGEs)主要以独立矿物的形式存在。铂族矿物(PGMs)多为铂和钯的砷化物、碲化物,如砷铂矿、砷钯矿、黄碲钯矿、碲钯矿等;主要分布于硅酸盐矿物中,其次为硫化物边缘,部分分布于磁铁矿边缘;铂族矿物成因主要有岩浆成因和热液成因2种。岩浆作用形成的铂族矿物分布于硅酸盐矿物中或硫化物边缘,硅酸盐中的铂族矿物是早期PGE与半金属元素形成的纳米团簇颗粒随岩浆演化形成矿物颗粒,被结晶的硅酸盐矿物包裹;分布于硫化物边缘的铂族矿物是残余熔浆结晶的结果。热液作用将PGE以类质同象的形式富集于钛磁铁矿单辉岩的部分矿物中,如热液蚀变较强烈的黄铜矿中含有较高的Rh,这也与铂族矿物集中分布在钛磁铁矿单辉岩中一致。 相似文献
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遵义黄家湾下寒武统底部Mo-Ni-PGE矿中铂族元素赋存形态分析及成因意义 总被引:5,自引:1,他引:5
本项目采用6级不同化学物相形态系统,用化学试剂选择性提取和对比提取相结合的方法,研究了PGE元素及Au的物相分布特点.得出了Ru、Rh、Pd、Os、Ir、Pt及Au在各物相中的含量及相对比率,参照电子探针等对Mo、Ni硫化矿物分析成果,表明PGE在镍的硫化物相中丰度较高外,在可交换态、黄铁矿态及残渣态等中亦有一定分布,显示PGE元素以超微细粒分散赋存特点.表明矿体在沉积时未发生PGE元素的显著成矿分异,成岩期也未出现明显的再次富集作用.此矿床系我国黑色岩系中确凿伴生有PGE矿的典型代表,铂族元素赋存状态研究对其成因、寻找和开发有关键意义. 相似文献
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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
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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
18.
I. A. Tararin V. M. Chubarov E. K. Ignat’ev S. V. Moskaleva 《Russian Journal of Pacific Geology》2007,1(1):82-97
The geology and mineralogy of host metamorphic rocks, the mineralogy of sulfide ores, and the distribution of PGE mineralization were studied in detail for the Kvinum-1 and Kvinum-2 copper-nickel occurrences of the Kvinum ore field, which are the most promising targets for the copper-nickel-PGE mineralization of the Sredinny Range of Kamchatka. It was established that stringer-disseminated and massive copper-nickel ores are localized in amphibole peridotites, cortlandites, and form ore bodies varying from tens of centimeters to 5–20 m thick among the layered cortlandite-gabbroid massifs. The massive sulfide ores were found only at the bottom of cortlandite bodies and upsection grade into stringer-disseminated and disseminated ores. Pyrrhotite, chalcopyrite, and pentlandite are the major ore minerals with a sharply subordinate amount of pyrite, sphalerite, galena, arsenopyrite, and löllingite. Besides pentlandite, the Ni-bearing minerals include sulforasenides (gersdorffite), arsenides (nickeline), and tellurides (melonite) of nickel. It was found that PGE mineralization represented by antimonides (sudburyite) and tellurobismuthides (michenerite) of Pd with sharply subordinate platinum arsenide (sperrylite) is confined to the apical parts of massive sulfide zones and the transition zone to the stringer-disseminated ores. Ore intervals enriched in arsenides and tellurides of Ni, Pd, and Bi contain high-purity gold. In the central parts of the orebodies, the contents of PGE and native gold are insignificant. It is suggested that the contents of major sulfide minerals and the productivity of PGE mineralization in the cortlandites are defined by combined differentiation and sulfurization of ultramafic derivatives under the effect of fluids, which are accumulated at the crystallization front and cause layering of parental magmas with different sulfur contents. The fluid-assisted layering of mafic-ultramafic massifs resulted in the contrasting distribution of PGM in response to uneven distribution of sulfur (as well as As, Te, and Bi) during liquid immiscibility. The productivity of PGE mineralization significantly increases with increasing contents of S, As, Te, and Bi (elements to which Pt and, especially, Pd have high affinity) in fluids. 相似文献
19.
Platinum-group minerals (PGM) in primary ores and placers are compared in order to substantiate prospecting guides for layered
and differentiated intrusions containing sulfide Cu-Ni ores with platinum-group elements (PGE). It is shown that supergene
placer mineral assemblages bear information on primary sources and their probable economic value. The mineralogical and geochemical
data on the large Siberian intrusions that host Cu-Ni and low-sulfide PGM deposits (Noril’sk 1, Kingash, Chinei, and Yoko-Dovyren)
are used to elaborate mineralogical prospecting guides based on the comparative study of PGM assemblages in primary ore, heavy
concentrate halos, and hillside sediments. The mechanism of PGM redistribution under supergene conditions is exemplified in
the Chinei deposit. The placer mineral assemblage with prevalence of Pt-Fe alloys, atokite-rustenburgite, sperrylite, and
multicomponent Pd-Sn-Cu-Pb compounds can be used as a prospecting guide for Noril’sk-type primary PGM ore and related economic
placers. The paolovite-sperrylite or sperrylite PGM assemblage in heavy concentrate halos indicates occurrence of Cu-Ni ore
in the prospecting area. Sperrylite with isomorphic admixture of Ir and Os typical of the Kingash pluton could be a orospecting
guide for Ni-bearing mafic-ultramafic intrusions. 相似文献
20.
The paper discusses the results of studying the contents of platinum group elements (PGE) and platinum group minerals (PGM) in ores of the Kingash deposit. The bulk of PGE has been established as concentrated in disseminated sulfide chalcopyrite–pyrrhotite–pentlandite ore and is represented by palladium bismuth–tellurides. During melt differentiation, the content and relationship of PGE are changed; the Pd/Pt value increases (up to 1.9 and 4.2 in dunite and wehrlite, respectively) with decreasing Mg number. The distribution of PGE, sulfur, and REE in various ore types suggests two formation mechanisms of high-grade ores: (1) the product of liquid immiscibility and gravity separation at the early magmatic stage and (2) involvement of the residual melt saturated in volatiles, which contributed to transportation and segregation of PGE at the late magmatic stage. The evolution of the ore system of the Kingash massif is characterized by sequential enrichment of PGM in Ni from high-Mg to low-Mg rocks similarly to sulfide minerals of disseminated ore. The criteria for ore content in utramafics of the Kansk block have been identified based on compared ore element and PGE concentrations in ultramafic rocks of the Kingash and Idar complexes. 相似文献