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1.
Yarlongite: A New Metallic Carbide Mineral   总被引:1,自引:0,他引:1  
Yarlongite occurs in ophiolitic chromitite at the Luobusha mine (29°5′N 92°5′E, about 200 km ESE of Lhasa), Qusum County, Shannan Prefecture, Tibet Autonomous Region, People’s Republic of China. Associated minerals are: diamond, moissanite, wüstite, iridium (“osmiridium”), osmium (“iridosmine”), periclase, chromite, native iron, native nickel, native chromium, forsterite, Cr-rich diopside, intermetallic compounds Ni-Fe-Cr, Ni-Cr, Cr-C, etc. Yarlongite and its associated minerals were handpicked from a large heavy mineral sample of chromitite. The metallic carbides associated with yarlongite are cohenite, tongbaite, khamrabaevite and qusongite (IMA2007-034). Yarlongite occurs as irregular grains, with a size between 0.02 and 0.06 mm, steel-grey colour, H Mohs: 5?-6. Tenacity: brittle. Cleavage: {0 0 1} perfect. Fracture: conchoidal. Chemical formula: (Cr4Fe4Ni)Σ9C4, or (Cr,Fe,Ni)Σ9C4, Crystal system: Hexagonal, Space Group: P63/mc, a = 18.839(2) ?, c = 4.4960 (9) ?, V = 745.7(2) ?3, Z = 6, Density (calc.) = 7.19 g/cm3 (with simplified formula). Yarlongite has been approved as a new mineral by the CNMNC (IMA2007-035). Holotype material is deposited at the Geological Museum of China (No. M11650).  相似文献   

2.
Luobusaite: A New Mineral   总被引:6,自引:0,他引:6  
A group of mantle minerals including about 70-80 subtypes of minerals are discovered from a podiform chromitite in Tibet, China. Recovered minerals include diamond, coesite, moissanite, wustite, Fe-silides and a new mineral, luobusaite. All of these minerals were hand-picked from heavymineral separates of the podiform chromitite in the mantle peridotite of an ophiolite. The grains of luobusaite are as host mineral with inclusions of native silicon or as an intergrowth with native silicon and Fe-Si phase. Luobusaite occurs as irregular grains, with 0.1-0.2 mm in size, consisting of very finegrained aggregates. The mineral is steel-grey in color, metallic luster, and opaque. The empirical formula (based on 2 for Si) is Fe0.83Si2, according to the chemical compositions of luobusaite. X-ray powder-diffraction data: orthorhombic system, space group Cmca, a = 9.874 (14) A, b = 7.784 (5) A, c= 7.829(7) A, Z=16.  相似文献   

3.
西藏蛇绿岩中二种合金矿物新变种   总被引:5,自引:0,他引:5  
在西藏雅鲁藏布江蛇绿岩带的东部,距拉萨200km的泽当罗莎蛇绿岩的铬铁矿中,发现有种类繁多的合金矿物,铬铁镍矿和依铁镍矿就是其中二种。铬铁镍矿分子式:Ni0.41Fe0.35Cr0.24,为等轴晶系,空间群为Fm3m,晶胞参数a=0.35622(2)nm。铱铁镍矿分子式:Ni0.66Fe0.18Ir0.16,属等轴晶系,空间群Oh^5-Fm3m,晶胞参数a=0.46486(4)mm。  相似文献   

4.
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   

5.
The results of study of the Bobruisk ring structure (Republic of Belarus) containing ~80 rare rockforming and accessory minerals are reported. Among them are native (Fe, Cu, Sn, Zn, Pb, Ag, Mo, W, Al) and intermetallic (Fe, Cr, Ni, Mo, B, N, C, Si) compounds, natural alloys (Fe–Cr, Fe–Cr–Mo–W–B; brass (Cu–Zn–Pb); and bronze (Sn–Pb–Zn–Cu)). They are observed as segregations of various shapes and sizes, as well as their aggregates. The formation of mineralization is controlled by reduced mantle fluids enriched in H2, CH4, CO, Si, N, and O and stimulating accumulation of rare elements as native and intermetallic phases, alloys, rather than isomorphic impurities in minerals.  相似文献   

6.
在山东蒙阴金伯利宕的副矿物蒙山矿中,首次发现了成分为柱红石类的新矿物相。对其成分进行探针分析,其一般晶体化学式可写为:A1.499~1.787B1.548~2,317C5.675~6.354O16。其中,A=K、Ba、Na、La;B=Cr、Fe、Mg、V;C=Ti、Zr、Nb等,平均计算化学式为:(K1.256Ba0.241Na0.085La0.046)1.628(Cr1.817Fe0.321Mg0.085V0.093)1.816(Ti6.015Zr0.075Nb0.039)6.119O16.理想化学式K2Cr2Ti6O16;相当于Redledgeite(BaCr2Ti6O16)[1]的K端元,且与南非OrangeFree州StarMine及NewEland新发现的K-Ba-Vtitanates(钛酸盐)[2,3]具有成分上的可比性。为使柱红石亚族矿物的命名系统化,本文采用主要大阳离子(K、Ba)与变价元素(Fe、Cr、V)为端元组分的命名原则,将新种命名为K-Cr柱红石。根据国外资料对柱红石亚族矿物Redlcdgeite的成分修正[1,4]建议将其原中文译名“硅镁铝钛矿”[5,6]更正为“Ba-Cr柱红石”。新种与蒙阴近年来发现的沂蒙矿、蒙山矿一起,组成了含大阳离子及硅酸盐不相容元素的复杂钛铬铁氧化物组合,皆以K、Cr为特征,从而与南非以Ba为主,含V的这类矿物形成区域对比。  相似文献   

7.
一种未定名的硫盐矿物——Pb_6Bi_7(Cu,Ag)S_(17)   总被引:1,自引:0,他引:1  
在河北省涞源的铜铁矿床中,发现了一种未定名的Pb-Bi-Cu的硫盐矿物,它以不规则粒状产于黄铜矿之中,与它共生的有方铅矿、闪锌矿、碲银矿、硫银铋矿和自然银等。该矿物是铅灰色,金属光泽,直径0.003—0.72mm,在显微镜下呈白色微蓝,双反射弱,非均质性明显,H_v=119.75kg/mm~2(50g),D_x=7.04g/cm~3。六个颗粒的平均化学成分值是Pb 36.51,Bi 44.80,S 15.35,Cu 1.82,Ag 1.54,Cr0.105,总计100.135。理论化学式为Pb_6Bi_7(Cu,Ag)S_(17),其中Cu>Ag。X射线衍射的强线值:3.428(10,012),3.059(4.140),2.996(9,041),2.765(5,207),2.247(4,250),2.023(3,133);晶胞参数a=8.811,b=13.060,c=7.106,~(?)_(?)V=817.699~3。Z=1,斜方晶系。  相似文献   

8.
We report highly unusual platinum-group mineral (PGM) assemblages from geologically distinct chromitites (banded and podiform) of the Kraubath massif, the largest dismembered mantle relict in the Eastern Alps. The banded chromitite has a pronounced enrichment of Pt and Pd relative to the more refractory platinum-group elements (PGEs) of the IPGE group (Os, Ir, Ru), similar to crustal sections of ophiolites. On the contrary, the podiform chromitite displays a negatively sloping chondrite-normalised PGE pattern typical of ophiolitic podiform chromitite. The chemical composition of chromite varies from Cr# 73-77 in the banded type to 81-86 in the podiform chromitite. Thirteen different PGMs and one gold-rich mineral are first observed in the banded chromitite. The dominant PGM is sperrylite (53% of all PGMs), which occurs in polyphase assemblages with an unnamed Pt-base metal (BM) alloy and Pd-rich minerals such as stibiopalladinite, mayakite, mertieite II, unnamed Pd-Rh-As and Pd(Pt)-(As,Sb) minerals. This banded type also contains PGE sulphides (about 7%) represented by a wide compositional range of the laurite-erlichmanite series and irarsite (8%). Os-Ir alloy, geversite, an unnamed Pt-Pd-Bi-Cu phase and tetrauricupride are present in minor amounts. By contrast, the podiform chromitite, which yielded 21 different PGMs, is dominated by laurite (43% of all PGMs) which occurs in complex polyphase assemblages with PGE alloys (Ir-Os, Os-Ir, Pt-Fe), PGE sulphides (kashinite, bowieite, cuproiridsite, cuprorhodsite, unnamed (Fe,Cu)(Ir,Rh)2S4, braggite, unnamed BM-Ir and BM-Rh sulphides) and Pd telluride (keithconnite). A variety of PGE sulpharsenides (33%) including irarsite, hollingworthite, platarsite, ruarsite and a number of intermediate species have been identified, whereas sperrylite and stibiopalladinite are subordinate (2%). The occurrence of such a wide variety of PGMs from only two, 2.5-kg chromitite samples is highly unusual for an ophiolitic environment. Our novel sample treatment allowed to identify primary PGM assemblages containing all six PGEs in both laurite-dominated podiform chromitite as well as in uncommon sperrylite-dominated banded chromitite. We suggest that the geologically, geochemically and mineralogically distinct banded chromitite from Kraubath characterises the transition zone of an ophiolite, closely above the mantle section hosting podiform chromitite, rather than being representative of the crustal cumulate pile.  相似文献   

9.
In the Noril’sk ore field, parkerite is a characteristic mineral of sulfide ore that metamorphosed under conditions of zeolite and prehnite-pumpellyite facies and of arsenide-calcite veins. The mineral occurs in ores containing bornite, anhydrite, magnetite, mackinawite (3–5 wt % Ni), valleriite, calcite, ankerite, native silver, native bismuth, violarite, Te-rich bismutohauchecornite, cupropentlandite enriched in Fe, Pd-rich breithauptite (1.5–2.5 wt % Pd), galena enriched in Cu (3.8 wt % Cu), and Ni arsenides and antimonides. Parkerite occurs in those place, where the primary ores have contained pockets and veins of graphic galena and chalcopyrite aggregates with associated Pt-Pd-Au-Ag minerals. Parkerite metacrysts in galena and Fe-Cu-Ni sulfides contain 6–16 and up to 5 wt % Pb, respectively. Parkerite rims replacing PGM aggregates and galena contain 1–3 wt % Pb. In calcite veins hosted in metamorphosed sulfide ores, parkerite is associated with native silver and bismuth, maucherite, cobaltite, chalcocite, and uraninite. Parkerite from these veins contains up to 0.5 wt % Pb. Thus, the Pb and Bi contents in parkerite basically depend on those of replaced minerals. Rare bismutohauchecornite is associated with parkerite.  相似文献   

10.
Chengdeite occurs in chromite orebodies in dunite as well as in placers in their neighbourhood. The mineral occurs as granular aggregates in association with inaglyite and in some cases occurs as graphic intergrowths with native iridium. It is opaque with a metallic lustre, colour steel-black, streak black,HM = 5.2, VHN50=452 kg/mm2, cleavage not observed, fracture not observed, strongly magnetic. Its reflection colour is bright white with a yellowish tint. It has no internal reflection, bireflectance or pleochrism, and shows isotropism.Thirteen chemical analyses were carried out by means of the electron microprobe. The mean percentages of the data obtained in the 13 analyses ares S 0.001, Fe 7.9, Ni 0.03, Co 0.03, Cu 0.83, As 0.02, Rh 0.19, Pd 0.00, Os 0.06, Ir 88.5, Ft 2.2 and Pb 0.00. The simplified formula is Ir3Fe, which requires Ir 91.17 and Fe 8.83, the total being 100.00 (% ).Five strongest lines of X-ray powder diffraction (hkl, d, I)are: 111, 2.18 (80);200, 1.89 (60); 220, 1.34 (70);311, 1.142  相似文献   

11.
蛇绿岩中铬铁岩母岩浆的富Ca特征:矿物包裹体证据   总被引:1,自引:0,他引:1       下载免费PDF全文
铬铁矿作为蛇绿岩中的重要矿产,其成矿母岩浆性质及演化一直存在较大争议.铬铁矿的矿物包裹体同时或先于铬铁矿结晶,其成分和类别能很好地记录成矿母岩浆性质和演化过程.土耳其Pozant?-Karsant?蛇绿岩不同类型铬铁岩的铬铁矿中发现了多种类型包裹体:不含水硅酸盐矿物(如橄榄石和单斜辉石)、含水硅酸盐矿物(如角闪石和金云母)、复合型矿物包裹体(如蛇纹石、硅灰石和单斜辉石的复合型包裹体)和不常见矿物(如磷灰石、铂族元素硫化物).含水矿物包裹体的出现以及矿物的高Mg#特征(如橄榄石Fo=95.4~97.1;单斜辉石Mg#=92.0~99.9;角闪石Mg#=88.9~99.8)表明结晶铬铁矿的母岩浆具有富水、富Mg的特征.同时,除钙铬榴石和磷灰石的包裹体外,在铬铁矿中首次发现富Ca矿物方解石和硅灰石,其中方解石和菱镁矿以复合型包裹体形式产出,硅灰石则分布于蛇纹石矿物包裹体中.这些富Ca矿物的出现以及硅酸盐矿物的高CaO含量均揭示了铬铁岩母岩浆的富Ca特征.母岩浆中的Ca组分可能来源于俯冲板块中富Ca岩石/矿物的部分熔融,Ca离子的大量出现使得Cr3+在熔体中更加稳定,同时富Ca矿物的结晶促进了岩浆中Cr的进一步富集而利于铬铁矿的大量结晶沉淀.   相似文献   

12.
西藏罗布莎不同类型铬铁矿的特征及成因模式讨论   总被引:6,自引:2,他引:4  
蛇绿岩地幔橄榄岩中产出的豆荚状铬铁矿是铬的主要来源。已有的研究表明,豆荚状铬铁矿形成于洋中脊或俯冲带的浅部地幔环境。但随着近些年在豆荚状铬铁矿及围岩地幔橄榄岩中不断发现金刚石等深部矿物,人们也开始质疑豆荚状铬铁矿的浅部成因理论。本文系统研究了西藏雅鲁藏布江蛇绿岩带东段的罗布莎豆荚状铬铁矿床,识别出两类铬铁矿,一类以方辉橄榄岩为围岩的致密块状铬铁矿(Cr1#),另一类是以纯橄岩壳为围岩的浸染状铬铁矿(Cr2#)。两类铬铁矿在铬尖晶石的矿物化学成分、PGE和Re-Os同位素特征上存在较大差别,属不同演化过程的结果。地幔橄榄岩的地球化学特征指示罗布莎橄榄岩中存在由低铬且轻稀土亏损和高铬且轻稀土富集的两类方辉橄榄岩。在此基础上,提出豆荚状铬铁矿为多阶段形成的新认识,经历了早期俯冲至地幔过渡带(410~660km)的陆壳和洋壳物质被脱水和肢解,过渡带产生的热和流体促成了地幔的熔融和Cr的释放和汇聚;铬铁矿浆在地幔柱/地幔对流驱动下,运移至过渡带顶部冷凝固结,并有强还原性的流体进入,后者携带了深部形成的金刚石、斯石英等高压矿物,并进入"塑性-半塑性地幔橄榄岩"中;随着物质向上移动,深度降低,早期超高压相矿物发生相变,如斯石英转变成柯石英,高压相的铬铁矿中出溶成柯石英和单斜辉石;在侵位过程和俯冲带环境,含水熔体与方辉橄榄岩反应形成了不含超高压矿物的规模相对较小的浸染状铬铁矿(Cr2#)及纯橄岩壳。  相似文献   

13.
豆英状铬铁矿按其矿物化学组分分为高铝型(Cr#值为20~ 60)和高铬型(Cr#值为60~80)两类(Thayer,1970),在全球已报道的豆英状铬铁矿中普遍为在一岩体内只存一种类型的矿体,而在同一岩体内发现两种类型的铬铁矿体较少见.位于雅鲁藏布江缝合带西段普兰岩体中首次发现同时存在高铬型和高铝型铬铁矿,岩体由地幔橄榄岩、辉长辉绿岩、火山岩等组成.地幔橄榄岩主要为方辉橄榄岩、纯橄岩和少量二辉橄榄岩.在方辉橄榄岩中发现7处透镜状的铬铁矿矿体露头,矿石类型主要有致密块状、稠密浸染状和稀疏浸染状等.矿体长2~6m,厚0.5~2m,矿体的最大延伸方向为北西-南东向,与岩体的展布方向一致,矿石的Cr#=52~88,高铬型铬铁矿包括Cr-2~5矿体,Cr#值为63~89,高铝型铬铁矿有Cr-1和Cr-6矿体,Cr#=52 ~55.矿石中脉石矿物主要为橄榄石、角闪石、蛇纹石等.普兰地幔橄榄岩的矿物结构显示,岩体经历了强烈的部分熔融以及塑性变形作用,地幔橄榄岩的地球化学特征显示岩体形成于MOR,后受到SSZ环境的改造.并且依据铬尖晶石-橄榄石/单斜辉石的矿物化学成分,识别出普兰地幔橄榄岩至少经历了3次不同的部分熔融,包括早期部分熔融(~10%)、晚期部分熔融(20%~30%)和局部的减压部分熔融作用(~15%).对比其他铬铁矿矿体和地幔橄榄岩的矿物组合,矿物化学和地球化学等,显示普兰豆荚状铬铁矿矿体与典型高铬型、高铝型铬铁矿具相似性,并存在较大的找矿空间.  相似文献   

14.
西藏蛇绿岩地幔中的主要自然金属矿物   总被引:9,自引:0,他引:9  
在西藏雅鲁藏布江蛇绿岩带的罗布莎蛇绿岩块的豆荚状铬铁矿床中 ,揭示出一个由 70~ 80种矿物组成的地幔矿物群 ,包括自然金属、合金、硫 (砷 )化物、氧化物和硅酸盐等。这些矿物呈包裹体或脉石产于铬铁矿石中 ,经人工重砂分析 ,自然元素矿物有自然硅、自然铁、自然锌、自然铅、自然铝、自然铬、自然锡、自然镍、自然钨、自然钛、自然锇、自然铱、自然钌、自然钯、石墨、金刚石、自然金和自然银等。文中选择一些自然元素矿物 ,探索这些地幔矿物特点以及蛇绿岩和铬铁矿的形成机制。根据共生矿物群以及罗布莎地幔橄榄岩为新鲜的未蛇纹石化的岩石 ,认为罗布莎自然元素矿物与蛇纹石化作用无关。它们可能是在地核形成时期滞留于地幔中的成核物质 ,抑或是核幔之间化学反应的产物 ,后来被铬铁矿矿浆捕获 ,并同铬铁矿一起由地幔柱作用和板块作用侵位于浅部并仰冲出露于地表。  相似文献   

15.
Minerals of native elements (Pd, Pt, Au, Ag, and Au-Ag solid solutions) as well as Pb, Zn, Cu, Bi, Fe, Cr, Ni, W, Al, and their intermetallides, and a number of other ore minerals were discovered in brown coals of the Erkovets field. The structural reorganization of the noble metal grains and most of the other minerals found in the brown coals suggest their authigenic paragenesis. The input of noble metals in brown coals is possible in an ionic mode from the surface and underground waters as mineral particles transported by wind from goldfields.  相似文献   

16.
於祖相 《矿物学报》1998,18(2):134-137,T001
富碲马营矿产在纯橄榄岩铬矿体中。在铝矿石及矿体附近的砂矿中均可找到。呈粒状自形结构,直径0.01~0.15mm。与硫铱矿(IrS2)、双峰矿、高台矿、马营矿及(Fe,Ni)9Cu3Ir6S20等紧密共生。有的呈脉状,宽0.1~0.2mm,长1.2mm。金属光泽。不透明,钢灰色,粉末黑色。HM=3.7。VHN50=161kg/mm2(范围132~215kg/mm2)。无解理。无断口。性脆。计算密度为12.2g/cm3。反射色亮白带淡黄色调,内反射无,均质性,双反射与反射多色性无。5个电子探针分析数据平均为(%):Cu0.3,Te32.9,Ir34.7,Pt2.7,Bi28.2,总量98.9。实验式根据原子数3计算为:(Ir(0.92)Pt(0.92)Cu(0.01));(1.00)Bi(0.68)Te(1.31)。简化后的理论式为Ir(Te,Bi)2,而(Ir:Bi:Te=3:2:4)。6条富碲马营矿是强X射线衍射hki、d、I为:210,2.89(60);311,1.95(100);511,1.246(70);520,1.204(60);440,1.145(60);533,0.9891(60)。根据X射线粉晶指标化求得马营矿为等轴晶系,空间群:Pa3,a=0.6486(4)um,V=0.2729nm3,Z=4。富碲马营矿是本文作者对马营矿研究的继续与补充。  相似文献   

17.
1 Introduction The association of massive Fe-Ni-Cu sulfides andchromite is a very unusual feature of podiformchromitites occurring in mantle tectonites of ophioliticcomplexes. It has only been described in theSoutheastern Desert, Egypt, where sulfides a…  相似文献   

18.
Oxides, sulfides, arsenides, native metals, and intermetallic compounds are accessory ore minerals from the rocks of the Mt. Poputnaya ultramafic massif. The Fe–Ni phases containing 55.3–82.3 wt % Ni are the most abundant among them. Magnetite, pyrrhotite, Co–Fe and Fe–Ni phases, and native iron are the comparatively high-temperature minerals, whereas heazlewoodite, orcelite, dienerite, and native copper are formed at low temperatures. The found minerals result from serpentinization at 500°C and below.  相似文献   

19.
本文对发现于河南毛堂金矿田氧化矿石中的含锡自然铜进行了矿物学研究。该矿物属等轴晶系,O_h~5-F_(m3m),a_0=3.655?,Z=4。化学成分中Cu 90.38(wt)%,Sn 9.38(wt)%,分子式Cu_(18)Sn。含锡自然铜相当于Cu_(18)Sn合金中的a相,在自然界属首次发现。  相似文献   

20.
铋砷黝铜矿在中国的发现与研究   总被引:1,自引:0,他引:1  
铋砷黝铜矿产于广东陆丰中低温热液黄铁矿矿床中,呈它形粒状嵌布在黄铁矿内,粒径0.05~0.22mm,与黄铜矿、针硫铋铝矿共生。反射免呈灰色微带蓝色,均质性。显微硬度Hv=295.5kg/mm2。电子探针成分分析(平均值)为:S24.4%,Cu38.25%,As13.03%,Bi17.人83%,Sb0.48%,Zn2.39%,Fe2.13%,Te1.47%,化学式为:Cu10(Fe0.65Zn0.63Cu0.49)1.77(As2.97Bi1.46Sb0.07)4、50(S12.8Te0.20)13。X射线粉晶衍射强线:2.95(10),2.55(3),1.866(5),1.727(4),1.041(5)。晶胞参数α=1.0218nm。  相似文献   

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