共查询到19条相似文献,搜索用时 187 毫秒
1.
青海化隆地区拉水峡铜镍矿床地质、
地球化学特征及成因 总被引:3,自引:1,他引:2
拉水峡铜镍矿床位于化隆基性—超基性岩带中,岩体几乎全岩发生铜、镍硫化物矿化,且已遭受强烈蚀变,以角闪岩为主。岩浆期主要金属硫化物矿物组合为磁黄铁矿、黄铜矿、镍黄铁矿;热液蚀变期主要有紫硫镍矿、黄铁矿、黄铜矿、针镍矿等;氧化表生期主要为含镍高岭石、含镍绿泥石、孔雀石等。矿石轻稀土元素富集和负Eu异常明显,说明岩浆演化过程中发生了大量斜长石等的分离结晶作用。∑PGE含量平均为2460.46×10-9,(Pd+Pt)/(Os+Ir+Ru)值为0.40~2.00,表明铂族元素与岩浆深部熔离作用密切相关;但Pt/Pd(0.01~2.62)、Pd/Ir(0.91~8.77)说明热液作用对铂族元素具有一定的富集作用。S同位素组成变化范围很小,δ34S平均值为2.24‰,硫化物中的S以地幔S为主。拉水峡矿床的形成经历了岩浆融离贯入、热液叠加改造及表生氧化作用3个阶段。 相似文献
2.
祁连山拉水峡铜镍硫化物矿床矿物学、地球化学及成因 总被引:1,自引:0,他引:1
拉水峡中型铜镍矿床几乎全岩矿化。矿石矿物学、矿床地球化学的研究表明,矿石中金属硫化物以紫硫镍铁矿、黄铁矿、黄铜矿为主,热液作用使原生硫化物组合发生了改变,低温热液特征的元素As、Se、Ag、Te富集; 矿石中Ni含量远高于Cu含量,不同类型矿石均属轻稀土富集型,反映了相同的岩浆成因,部分熔融来源特点。热液改造致使块状矿石中Cu/Ni、Ni/Co比值较高,REE分馏程度明显高于原生浸染状矿石;矿石中铂族元素含量平均为2460.5×10-9,具有较高的Ir含量和低的Pd/Ir比值特点,铂族元素与岩浆深部融离作用密切相关,块状矿石Pd/Ir比值和(Pt+Pd)/(Os+Ir+Ru)比值均高于原生浸染状矿石,表明热液作用对Cu、Pt、Pd金属元素富集具有一定作用;岩浆期后流体属中低温度(180~244℃)、中等盐度(8.81~14.67%NaCl)、中等密度(0.86~0.95g/cm3)范围, CH4+N2+CO2成分组合,具有岩浆流体成分特征。综合分析认为,拉水峡矿床主体成因可能仍以岩浆深部曾有过较彻底的硫化物不混熔作用为主,后期经历了热液作用改造。 相似文献
3.
《矿物岩石地球化学通报》2016,(1)
香山铜镍矿床是东天山觉罗塔格成矿带北缘中型铜镍矿床,资源前景颇佳。对香山铜镍矿床中富铜矿石、富镍矿石和浸染状矿石内磁黄铁矿、镍黄铁矿和黄铜矿进行了电子探针分析,以期研究铂元素的富集机制。结果表明,磁黄铁矿和镍黄铁矿早于黄铜矿形成,更富集Co和Se元素,黄铜矿则富集Sb、Bi和Zn等低温元素。Pt元素主要通过岩浆作用富集,但磁黄铁矿和镍黄铁矿中丰度更高,硫化物熔体分异不均衡是导致这种差异性的原因之一。富铜矿石全岩Pt元素含量最高,其原因是Pt元素热液活动性强,且富铜矿石经受了热液作用改造。 相似文献
4.
土墩铜镍矿床位于东天山黄山—镜儿泉铜镍成矿带的西端,具有较好的铜、镍资源前景。铜镍矿石中主要金属矿物为黄铜矿、磁黄铁矿、镍黄铁矿、磁铁矿以及黄铁矿等。在详细研究土墩铜镍矿床成矿地质背景的基础上,通过对土墩铜镍矿床中浸染状矿石和块状矿石中主要金属矿物进行电子探针原位测试发现,金属矿物中Pt含量较高,范围在490~2 450 g/t之间,平均为1 713 g/t,而Pd含量则较低。进一步研究Pt的赋存形式及矿石中伴生元素Co、Se、Ag、Sb等的元素地球化学特征,结果表明,晚期成矿热液对早期镍黄铁矿和磁黄铁矿的交代使Pt常发生扩散交代作用,这种热液改造作用对贵金属元素的活化和再富集具有重要意义。此外,土墩铜镍矿床中具有高Se含量、较低S/Se比值以及高R因子值的矿段是极有可能形成铂族元素(PGE)的矿化富集带。 相似文献
5.
对路北铜镍矿区主成矿元素、共伴生有益元素在矿体和矿石中的含量及变化特征进行分析研究。路北铜镍矿区Ni/Cu比值平均为1.73,介于东天山铜镍成矿带的中间值(1.11~2.20),与香山铜镍矿最接近。通过对不同品级矿石Ni/Cu比值分析,Pt,Se元素含量具显著差异,特富矿体中最富集(53.03×10~(-6)、33.6×10~(-6)),Pt,Ag,Se元素更趋向富集于晚期的矿浆中。采用电子探针对镍黄铁矿、黄铜矿、磁黄铁矿进行分析,镍黄铁矿中Co与Fe元素呈此消彼长的趋势,随着Fe含量减少,Co含量呈增加趋势,与黄山东铜镍矿一致。路北、黄山东、香山、图拉尔根、白石泉等铜镍矿区镍黄铁矿、黄铜矿、磁黄铁矿中S元素与标准式相比普遍偏高,表明主成矿期S元素充足,利于Ni,Cu等成矿元素从硅酸盐中析出与S结合成矿。通过对路北岩浆铜镍硫化物矿床矿体及矿石中有益元素的分析探讨,认为路北铜镍矿深部存在高纯度硫化物矿浆式铜镍矿体。 相似文献
6.
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
7.
位于芬兰北部中拉普兰绿岩带的克维特斯塔(Kevitsa)镍-铜-铂族元素矿床是世界上主要的岩浆镍-铜硫化物矿床之一。该矿床储量大,含丰富的镍-铜硫化物和铂族元素。对矿床产出环境、地质特征、矿床成因等进行了总结,结果表明:矿体主要赋存于克维特斯塔基性—超基性层状侵入体的超基性单元中。主要矿石类型为普通型和镍-铂族元素型2种,其中镍-铂族元素型矿石内橄榄石具极高的Ni含量。主要矿石矿物为磁黄铁矿、镍黄铁矿、黄铜矿、黄铁矿、针硫镍矿、红砷镍矿、砷镍矿、辉砷镍矿等,绝大部分铂族矿物包含在硅酸盐中和附着在硫化物颗粒边界。Re-Os、Sm-Nd、Sr及S同位素特征显示成矿岩浆为幔源,但受到地壳物质的混染作用。Pb同位素年代学结果表明克维特斯塔侵入体形成于古元古代。 相似文献
8.
金川铜镍硫化物矿床岩浆通道型矿体地质地球化学特征 总被引:7,自引:0,他引:7
金川铜镍硫化物矿床6行富铜(铂族)矿体曾因Cu、Pt、Pd等含量明显高于相邻其它矿体而被认为是岩浆期后热液叠加作用的产物,研究发现,空间上该矿体受断层构造控制,在矿石组构、矿物组成和硫同位素组成方面与相邻岩浆融离型1号矿体一致,显示了该矿体岩浆成矿作用的特征。在元素地球化学方面,6行富铜(铂族)矿体的Cu、Ni、Pt、Pd含量及Cu/Ni比值明显高于1号主矿体,而Os、Ir、Rh、Ru却明显低于后者,同时,前者相对富含LREE,轻、重稀土分异程度高于后者。根据硫化物结晶分异过程中金属元素分配规律及稀土元素特征,阐明了6行富铜(铂族)矿体为岩浆通道型矿体,是岩浆硫化物晚期结晶的产物。矿区中西部存在的Cu、Ni、Pt、Pd、Au等含量高,而Os、Ir、Rh、Ru含量低的部位,是寻找岩浆通道型矿体的有利部位。 相似文献
9.
煎茶岭硫化镍矿床的铂族元素地球化学特征及其意义 总被引:8,自引:2,他引:8
采用ICP-MS分析方法对煎茶岭硫化镍矿床岩石及矿石的铂族元素地球化学研究表明,煎茶岭矿床蛇纹岩的Cu/Pd值低于原生地幔岩浆的Cu/Pd值,说明岩浆熔离作用较弱,其Au/Pd值反映存在后期变质热液成矿作用镍矿石的Pd/Ir比值变化较小,指示其多数矿石属于岩浆型,尽管岩浆活动弱,但以岩浆成矿作用为主。该硫化镍矿床的铂族元素特征参数(Pt/(Pt Pd)、(Pt Pd)/(Ru Ir Os)、Pd/Ir及Cu/(Ni Cu)等)具有过渡特征,这与其处于过渡的构造环境、特殊的岩浆性质和复杂的成矿作用有关煎茶岭镍矿床成矿过程中有壳源物质的混染,整体上岩、矿石铂族元素含量较低,这与其岩浆熔离作用弱,PGE成矿作用不发育等因素有关 相似文献
10.
11.
Genesis of the Jinchuan PGE deposit, China: evidence from fluid inclusions, mineralogy and geochemistry of precious elements 总被引:3,自引:0,他引:3
Summary The Jinchuan deposit is a platinum group element (PGE)-rich sulfide deposit in China. Drilling and surface sampling show that
three categories of platinum group element (PGE) mineralization occur; type I formed at magmatic temperatures, type II occurs
in hydrothermally altered zones of the intrusion, and type III in sheared dunite and lherzolite. All ore types were analyzed
for Os, Ir, Ru, Rh, Pd, Pt and Au, as well as for Cu, Ni, Co and S. Type I ore has (Pt + Pd)/(Os + Ir + Ru + Rh) ratios of
<7 and relatively flat chondrite-normalized noble metal patterns; the platinum group minerals (PGM) are dominated by sperrylite
and moncheite associated with chalcopyrite, pyrrhotite and pentlandite. Type II has (Pt + Pd)/(Os + Ir + Ru + Rh) ratios from
40 to 330 and noble metal distribution patterns with a positive slope; the most common PGM are sperrylite and Pd bismuthotelluride
phases concentrated mostly at the margins of base metal sulfides. Type III ores have the highest (Pt + Pd)/(Os + Ir + Ru +
Rh) ratios from 240 to 710; the most abundant PGM are sperrylite and phases of the Pt–Pd–Te–Bi–As–Cl system. It is concluded
that the Jinchuan deposit formed as a result of primary magmatic crystallization followed by hydrothermal remobilization,
transport, and deposition of the PGE. 相似文献
12.
Small bodies of pyrrhotite, chalcopyrite, minor pentlandite, and magnetite occur at the peripheries of podiform bodies of chromite in ultramafic ophiolitic rocks at Tsangli, Eretria, central Greece. Banding of magnetite and sulfide within the bodies is reminiscent of magmatic banding. A magmatic origin has been proposed for similar sulfide masses in the Troodos ophiolite (Panayiotou, 1980). The compositions of the host rocks, chromite, and of the sulfides have been investigated. On average, the sulfide mineralization, recalculated to metal content in 100% sulfide, contains 0.55% Ni, 5.15% Cu, 0.29% Co, 9 ppb Pd, 179 ppb Pt, 16 ppb Rh, 112 ppb Ru, 31 ppb Ir, 58 ppb Os, and 212 ppb Au. These metal contents, particularly the high Cu/(Cu+Ni) ratio of 0.78 and the Pt/(Pd+Pt) ratio of 0.95, are inconsistent with the sulfides having reached equilibrium with their Ni rich host rocks at magmatic temperatures and accordingly it is concluded that they are not of magmatic origin. The average 34S value of the sulfide bodies is +2 while that of a sample of pyrite from country-rock schist is –15.6. These values are inconclusive as to the origin of the sulfur. It is suggested that the sulfides have been precipitated by hydrothermal fluids, possibly those responsible for the serpentinization of the host rocks. The source of the metals may have been the host rocks themselves. 相似文献
13.
The distribution of platinum group elements (PGEs) in massive sulfides and hematite–magnetite±pyrite assemblages from the
recently discovered basalt-hosted Turtle Pits hydrothermal field and in massive sulfides from the ultramafic-hosted Logatchev
vent field both on the Mid-Atlantic Ridge was studied and compared to that from selected ancient volcanic-hosted massive sulfide
(VHMS) deposits. Cu-rich samples from black smoker chimneys of both vent fields are enriched in Pd and Rh (Pd up to 227 ppb
and Rh up to 149 ppb) when compared to hematite–magnetite-rich samples from Turtle Pits (Pd up to 10 ppb, Rh up to 1.9 ppb).
A significant positive correlation was established between Cu and Rh in sulfide samples from Turtle Pits. PGE chondrite-normalized
patterns (with a positive Rh anomaly and Pd and Au enrichment), Pd/Pt and Pd/Au ratios close to global MORB, and high values
of Pd/Ir and Pt/Ir ratios indicate mafic source rock and seawater involvement in the hydrothermal system at Turtle Pits. Similarly
shaped PGE chondrite-normalized patterns and high values of Pd/Pt and Pd/Ir ratios in Cu-rich sulfides at Logatchev likely
reflect a similar mechanism of PGE enrichment but with involvement of ultramafic source rocks. 相似文献
14.
Chusi Li Edward M. Ripley Thomas Oberthür James D. MillerJr Gregory D. Joslin 《Mineralium Deposita》2008,43(1):97-110
Stratigraphic offsets in the peak concentrations of platinum-group elements (PGE) and base-metal sulfides in the main sulfide
zone of the Great Dyke and the precious metals zone of the Sonju Lake Intrusion have, in part, been attributed to the interaction
between magmatic PGE-bearing base-metal sulfide assemblages and hydrothermal fluids. In this paper, we provide mineralogical
and textural evidence that indicates alteration of base-metal sulfides and mobilization of metals and S during hydrothermal
alteration in both mineralized intrusions. Stable isotopic data suggest that the fluids involved in the alteration were of
magmatic origin in the Great Dyke but that a meteoric water component was involved in the alteration of the Sonju Lake Intrusion.
The strong spatial association of platinum-group minerals, principally Pt and Pd sulfides, arsenides, and tellurides, with
base-metal sulfide assemblages in the main sulfide zone of the Great Dyke is consistent with residual enrichment of Pt and
Pd during hydrothermal alteration. However, such an interpretation is more tenuous for the precious metals zone of the Sonju
Lake Intrusion where important Pt and Pd arsenides and antimonides occur as inclusions within individual plagioclase crystals
and within alteration assemblages that are free of base-metal sulfides. Our observations suggest that Pt and Pd tellurides,
antimonides, and arsenides may form during both magmatic crystallization and subsolidus hydrothermal alteration. Experimental
studies of magmatic crystallization and hydrothermal transport/deposition in systems involving arsenides, tellurides, antimonides,
and base metal sulfides are needed to better understand the relative importance of magmatic and hydrothermal processes in
controlling the distribution of PGE in mineralized layered intrusions of this type. 相似文献
15.
The Binchuan area of Yunnan is located in the western part of the Emeishan large igneous province in the western margin of the Yangtze Block.In the present study,the Wuguiqing profile in thickness of about 1440 m is mainly composed of high-Ti basalts,with minor picrites in the lower part and andesites,trachytes,and rhyolites in the upper part.The picrites have relatively higher platinum-group element(PGE) contents(ΣPGE=16.3-28.2 ppb),with high Cu/Zr and Pd/Zr ratios,and low S contents(5.03-16.9 ppm),indicating the parental magma is S-unsaturated and generated by high degree of partial melting of the Emeishan large igneous province(ELIP) mantle source.The slightly high Cu/Pd ratios(11 000-24 000) relative to that of the primitive mantle suggest that 0.007%sulfides have been retained in the mantle source.The PGE contents of the high-Ti basalts exhibit a wider range(ΣPGE=0.517-30.8 ppb).The samples in the middle and upper parts are depleted in PGE and haveεNd(260 Ma) ratios ranging from -2.8 to -2.2,suggesting that crustal contamination of the parental magma during ascent triggered sulfur saturation and segregation of about 0.446%-0.554% sulfides,and the sulfide segregation process may also provide the ore-forming material for the magmatic Cu-Ni-PGE sulfide deposits close to the studied basalts.The samples in this area show Pt-Pd type primitive mantle-normalized PGE patterns,and the Pd/Ir ratios are higher than that of the primitive mantle(Pd/Ir=1),indicating that the obvious differentiation between Ir-group platinum-group elements(IPGE) and Pd-group platinum-group elements(PPGE) are mainly controlled by olivine or chromites fractionation during magma evolution.The Pd/Pt ratios of most samples are higher than the average ratio of mantle(Pd/Pt=0.55),showing that the differentiation happened between Pt and Pd.The differentiation in picrites may be relevant to Pt hosted in discrete refractory Pt-alloy phase in the mantle;whereas the differentiation in the high-Ti basalts is probably associated with the fractionation of Fe-Pt alloys,coprecipitating with Ir-Ru-Os alloys.Some high-Ti basalt samples exhibit negative Ru anomalies,possibly due to removal of laurite collected by the early crystallized chromites. 相似文献
16.
《Geochimica et cosmochimica acta》2001,65(16):2789-2806
Fourteen peridotite xenoliths collected in the Massif Central neogene volcanic province (France) have been analyzed for platinum-group elements (PGE), Au, Cu, S, and Se. Their total PGE contents range between 3 and 30 ppb and their PGE relative abundances from 0.01 to 0.001 × CI-chondrites, respectively. Positive correlations between total PGE contents and Se suggest that all of the PGE are hosted mainly in base metal sulfides (monosulfide solid solution [Mss], pentlandite, and Cu-rich sulfides [chalcopyrite/isocubanite]). Laser ablation microprobe-inductively coupled plasma mass spectrometry analyses support this conclusion while suggesting that, as observed in experiments on the Cu-Fe-Ni-S system, the Mss preferentially accommodate refractory PGEs (Os, Ir, Ru, and Rh) and Cu-rich sulfides concentrate Pd and Au. Poikiloblastic peridotites pervasively percolated by large silicate melt fractions at high temperature (1200°C) display the lowest Se (<2.3 ppb) and the lowest PGE contents (0.001 × CI-chondrites). In these rocks, the total PGE budget inherited from the primitive mantle was reduced by 80%, probably because intergranular sulfides were completely removed by the silicate melt. In contrast, protogranular peridotites metasomatized by small fractions of volatile-rich melts are enriched in Pt, Pd, and Au and display suprachondritic Pd/Ir ratios (1.9). The palladium-group PGE (PPGE) enrichment is consistent with precipitation of Cu-Ni-rich sulfides from the metasomatic melts. In spite of strong light rare earth element (LREE) enrichments (Ce/YbN < 10), the three harzburgites analyzed still display chondrite-normalized PGE patterns typical of partial melting residues, i.e., depleted in Pd and Pt relative to Ir and Ru. Likewise, coarse-granular lherzolites, a common rock type in Massif Central xenoliths, display Pd/Ir, Ru/Ir, Rh/Ir, and Pt/Ir within the 15% uncertainty range of chondritic meteorites. These rocks do not contradict the late-veneer hypothesis that ascribes the PGE budget of the Earth to a late-accreting chondritic component; however, speculations about this component from the Pd/Ir and Pt/Ir ratios of basalt-borne xenoliths may be premature. 相似文献
17.
对新疆北山地区红石山镁铁-超镁铁质岩体中含铜镍的硫化物矿石和岩石进行了铂族元素和Re-Os同位素地球化学特征研究,结果表明,矿石及岩石的铂族元素(PGE)总量较低,变化于0.54×10-9~15.84×10-9之间。较低的Pd/Ir比值表明岩石主要受岩浆作用控制,后期热液作用影响不明显。较高的Cu/Pd和Ti/Pd比值表明岩浆在演化过程中发生了硫化物的熔离。岩体的母岩浆为有早期结晶橄榄石加入的高镁的玄武质岩浆。γOs(t)的变化较大,变化于-282~+282之间,表明有较多的地壳物质混入。地壳物质混染和橄榄石等矿物的分离结晶可能是引起岩浆中的S达到饱和进而熔离的重要因素。红石山岩体是经历了结晶分异和硫化物熔离后橄榄石的堆积体与残余岩浆演化的混合体。 相似文献
18.
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
19.
喀拉通克铜镍矿床铂族元素地球化学特征及其成矿作用意义 总被引:16,自引:7,他引:9
喀拉通克铜镍矿床位于准噶尔板块北缘,矿区主要矿体赋存于Y1-Y3号岩体中。矿石构造类型为致密块状和浸染状两大类,其中前者与后者呈贯入接触,不同浸染状类型之间为过渡关系。岩石和矿石的PGE总量偏低,且以PPGE为主,IPGE含量较低。整体上岩石中的PGE含量显示随基性程度降低而变小。矿石中的PGE含量随硫化物含量增加增大,显示PGE主要分布于硫化物熔离形成的物相中。100%硫化物计算后,矿石PGE含量平均仅为573×10-9。各岩体中浸染状矿石PGE组成并无明显差异;岩石和矿石具有相似的PGE分配模式,均属于Pt-Pd配分型。岩石Ni/Cu-Pd/Ir关系以及岩石地球化学资料显示,形成喀拉通克岩体的初始岩浆为MgO含量较高的玄武质岩浆,属于PGE不亏损的岩浆。基于PGE不亏损的大陆拉斑玄武岩初始岩浆推算,喀拉通克矿床母岩浆明显亏损PGE,而深部硫化物熔离可能是导致母岩浆PGE亏损的主要原因。岩石和矿石Pd/Pt比值总体特征,岩石Cr与Ni、Ir、Ru和Rh相关性,以及硫同位素和岩石学资料分析表明,初始岩浆在地壳深部发生的橄榄石、铬铁矿等矿物的分离结晶作用,可能是促使硫过饱和与深部熔离的主要因素。IPGE与PPGE分异特征及其相关分析,结合矿床宏观地质特征,推断该矿床浸染状矿的成矿作用经历了初始岩浆(PGE不亏损)→橄榄石等矿物分离结晶→硫化物深部熔离→成矿母岩浆(PGE亏损)→上侵并结晶分异的成矿过程。块状矿则可能是这一过程中PGE亏损的成矿母岩浆相对滞后熔离形成的硫化物熔体贯入的结果。 相似文献