Skergaard侵入体的PGE-Au矿化:贵金属矿物、岩石学和矿床成因

IF 2 4区 地球科学 Q1 GEOLOGY Geus Bulletin Pub Date : 2023-07-27 DOI:10.34194/geusb.v54.8306
N. Rudashevsky, T. Nielsen, V. Rudashevsky
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引用次数: 1

摘要

Skergaard PGE Au矿化,别名Platinova Reef,位于Skergaaard侵入体中上部区域的一套碗状宏观韵律层内的一系列矿化水平中。入侵暴露在东格陵兰68°N。由于其特殊的结构和矿物学,产状确定了其自身的类型。单个样本的实验室报告和同行评审的出版物中提供了丰富的矿物学数据,但这些数据都没有说明侵入辉长岩中PGE和Au共生体的横向和地层分布。在本研究中,我们整理和描述了第一次形成的富含PGE和最后一次形成的富金矿化水平的矿物学数据,并将其与岩石成因模型相结合。通过回收>4000粒贵金属相,可以详细研究其在整个矿化过程中的分布和成分、冷却过程中的再平衡、晶粒间关系以及与Cu-Fe硫化物和辉长岩主岩的关系。硫化物以斑铜矿、辉铜矿和少量黄铜矿为主。所有其他硫化物,如镍黄铁矿,都非常罕见。本研究中鉴定了54种不同的贵金属相,包括IMA批准的新矿物斯卡钙石(PdCu)、尼尔森石(Pd3Pb)和钠铁锰矿(Pd2Sb)。贵金属相包括(1)Cu和Pd的金属间化合物和合金;(2) Au和Cu(Ag)的金属间化合物和合金;(3) Pd、Cu的硫化物(Ag、Cd、Hg、Tl);(4) Pd(Pt,Ni)的砷化物和(5)Pd、Cu与Sn、Pb、Te(Sb,Bi)的金属间化合物。Skergaardite(PdCu)是较低且主要的PGE矿化水平(Pd5)中的主要PGE矿物。在侵入体的西边缘,它伴随着硫化硅岩(Pd16S7)和硫化硫化锌岩(PdS),但在东边缘,它很罕见,主要是铅质zvyagintsevite(Pd3Pb)。金相包括从AuCu3到天然金的一系列金属间化合物和合金,并以四AuCu3(AuCu)为主。黄金集中在各个矿化层的顶部和最上层的含贵金属矿化层,其次是富含铜的层状矿化层。贵金属共生体证明了从液相线到亚液相线温度的形成和重新平衡,并受到当地地球化学环境的控制。矿化是同岩浆作用,是剩余大块硅酸盐液体和晶体糊状物分馏和演化的结果。分馏导致硫化物饱和并形成不混溶的硫化物熔体液滴。随后与糊状熔体发生反应,并重新平衡至较低的温度,首先在屋顶下,然后在宏观韵律层的糊状物中滑到地板上。硫化物熔体液滴在1030–1050°C之间形成,并捕获贵金属。硫化物熔体和间隙富铁不混溶熔体在约1015°c下的后续反应,以及向共存熔体和流体的重新分布,导致PGE、Au和Cu的分离及其向上和向内迁移。岩浆流体以及富含挥发性的残余硅酸盐熔体保留在边缘的辉长岩中,并导致贵金属共生体与含水低温硅酸盐共生体平衡。
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The PGE-Au Mineralisation of the Skaergaard intrusion: precious metal minerals, petrography and ore genesis
The Skaergaard PGE-Au Mineralisation, alias the Platinova Reef, is hosted in a series of mineralisation levels within a suite of bowl-shaped macrorhythmic layers in the upper Middle Zone of the Skaergaard intrusion. The intrusion is exposed 68°N in East Greenland. The occurrence defines its own type due to its exceptional structure and mineralogy. A wealth of mineralogical data is available in laboratory reports for individual samples and in peer-reviewed publications, but none of these account for the lateral and stratigraphic distribution of PGE and Au parageneses in the gabbros of the intrusion. In this study, we collate and describe the mineralogical data for the first-formed PGE-rich and last-formed gold-rich mineralisation levels and integrate these with petrogenetic models. Recovery of >4000 grains of precious metal phases allow a detailed study of their distribution and compositions throughout the mineralisation, re-equilibration during cooling, inter-grain relationships and relationships to Cu-Fe sulphides and the gabbroic host rocks. The sulphides are dominated by bornite, chalcocite and minor chalcopyrite. All other sulphides, such as pentlandite, are very rare. Fifty-four different precious metal phases are identified in this study, and include the new IMA approved minerals skaergaardite (PdCu), nielsenite (Pd3Pb) and naldrettite (Pd2Sb). Precious metal phases include (1) intermetallic compounds and alloys of Cu and Pd; (2) intermetallic compounds and alloys of Au and Cu (Ag); (3) sulphides of Pd, Cu (Ag, Cd, Hg, Tl); (4) arsenides of Pd (Pt, Ni) and (5) intermetallic compounds of Pd, Cu with Sn, Pb, Te (Sb, Bi). Skaergaardite (PdCu) is the dominant PGE mineral in the lower and main PGE mineralisation level (Pd5). It is accompanied at the western margin of the intrusions by the sulphides vasilite (Pd16S7) and vysotskite (PdS) but is rare at the eastern margin, which is dominated by plumbide zvyagintsevite (Pd3Pb). Gold phases include a suite of intermetallic compounds and alloys from AuCu3 to native gold and are dominated by tetra-auricupride (AuCu). Gold is concentrated in the tops of individual mineralisation levels and in the uppermost precious metal–bearing mineralisation level, followed by stratiform Cu-rich mineralisation levels. Precious metal parageneses demonstrate formation and re-equilibration from liquidus to subsolidus temperatures and control by local geochemical environments. The mineralisation is syn-magmatic and the result of fractionation and evolution in the remaining bulk-silicate liquid and crystal mushes. Fractionation led to sulphide saturation and formation of immiscible sulphide melt droplets. This was followed by reaction with mush melts and re-equilibration to lower temperatures, first under the roof and subsequently after slumping to the floor in mushes of macrorhythmic layers. Droplets of sulphide melt formed between 1030–1050°C and trapped precious metals. The subsequent reaction between sulphide melt and interstitial Fe-rich immiscible melt at c. 1015°C, and redistribution to coexisting melt and fluid, led to the separation of PGE, Au and Cu and their up- and inward transport. Magmatic fluids as well as volatile-rich residual silicate melts were retained in gabbros at the margins and resulted in precious metal parageneses in equilibrium with hydrous low-temperature silicate parageneses.
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来源期刊
Geus Bulletin
Geus Bulletin GEOLOGY-
CiteScore
2.80
自引率
17.60%
发文量
8
期刊最新文献
Petrology of the Skaergaard Layered Series Stratigraphy of the Upper Jurassic to lowermost Cretaceous in the Rødryggen-1 and Brorson Halvø-1 boreholes, Wollaston Forland, North-East Greenland  Organic geochemistry of an Upper Jurassic – Lower Cretaceous mudstone succession in a narrow graben setting, Wollaston Forland Basin, North-East Greenland Upper Jurassic – Lower Cretaceous of eastern Wollaston Forland, North-East Greenland: a distal marine record of an evolving rift Mudstone diagenesis and sandstone provenance in an Upper Jurassic – Lower Cretaceous evolving half-graben system, Wollaston Forland, North-East Greenland
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