Cooperite and braggite from the Bushveld Complex: implications for the miscibility gap and identification

Merkle, R. K. W.; Verryn, S. M. C.

doi:10.1007/s00126-003-0347-2

Cited by 14 publications

(5 citation statements)

References 45 publications

(69 reference statements)

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“…Thus any important changes in composition of platinum-group minerals should occur mainly above the biotite closure temperature and less so under a slower cooling regime. This hypothesis is in agreement with the recent work by Merkle & Verryn (2003), which demonstrated that minerals such as braggite and cooperite equilibrate and change in composition above the blocking temperature of biotite. The clarification of the Bushveld Complex's lower-temperature thermal history would benefit from the application of (U þ Th)/He dating on apatite for example, recently shown (Min et al 2003) to be applicable to rocks more than twice as old as the Bushveld Complex.…”

Section: Discussionsupporting

confidence: 93%

⁴⁰ Ar/ ³⁹ Ar age constraints on ore deposition and cooling of the Bushveld Complex, South Africa

Nomade

Renne

Merkle

2004

JGS

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The UG-2 chromitite layer in the upper critical zone of the Rustenburg Layered Suite is one of the prominent platinum-group element enrichment zones of the c. 2.06 Ga Bushveld Complex (South Africa). Eleven biotite crystals were selected from a production concentrate from the Impala Platinum mine and degassed incrementally with a CO 2 laser. The apparent age spectra display widely varying characteristics, ranging from essentially 100% concordant to strongly discordant (in some cases undulatory) as a result of various degrees of chloritization of the grains. The least discordant spectra (seven grains, 90-100% 39 Ar released) yield integrated and plateau ages ranging from 2037 to 2049 Ma (relative to the Fish Canyon sanidine standard at 28.02 Ma) and share a weighted mean age of 2042.4 AE 3.2 Ma (2ó, excluding systematic errors). This age is slightly younger than existing constraints from U-Pb dating (c. 2055(c. -2061, which seem to indicate a cooling rate of around 20 8C/Ma. However, the recently inferred c. 1% bias between currently used calibrations of the 40 Ar/ 39 Ar and U-Pb systems implies a very rapid cooling rate for the Bushveld Complex between 700 and ,500 8C. The possibility of subtle bias as a result of recoil artefacts must be considered. In all cases, the heterogeneous age spectra yielded older apparent plateau ages, revealing the likelihood for erroneous conclusions to be drawn from less complete data sets.

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Section: Discussionsupporting

confidence: 93%

⁴⁰ Ar/ ³⁹ Ar age constraints on ore deposition and cooling of the Bushveld Complex, South Africa

Nomade

Renne

Merkle

2004

JGS

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“…Cooperite and braggite are dealt with together, as these minerals are hard to distinguish microscopically and they form a chemically nearly continuous series (Cabri 2002, Merkle & Verryn 2003. Notably, cooperite was found in the Makwiro and Umtebekwe Rivers, and braggite in the Makwiro River alone.…”

Section: Cooperite (Pts) and Braggite [(Ptpdni)s]mentioning

confidence: 99%

Detrital Platinum-Group Minerals in Rivers Draining the Great Dyke, Zimbabwe

Oberthür¹,

Weiser²,

Melcher³

et al. 2013

The Canadian Mineralogist

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The present work focuses on the description of the assemblage of detrital platinum-group minerals (PGM) found in rivers draining the Great Dyke. This PGM assemblage distinctly contrasts with the suite of PGM in the pristine, sulfide-bearing Main Sulfide Zone (MSZ) of the Great Dyke, the assumed source of the detrital PGM. Specifically, PGE-bismuthotellurides and-sulfarsenides, common in the MSZ ores, and PGE-oxides or-hydroxides present in the oxidized MSZ, are missing in the assemblage of detrital PGM in the fluvial environment. Instead, conspicuously high proportions of grains of Pt-Fe alloy are common in the sediments, followed by sperrylite, cooperite, braggite, laurite, rare Pd-Sb-As compounds, and Os-Ir-Ru alloys. Possibly, some of the Pt-Fe alloy grains originate from the MSZ, but the majority appear to represent true neo-formations that formed in the course of weathering of the MSZ ores and concomitant supergene redistribution of the ore elements. Sperrylite, cooperite/braggite, and laurite appear to be direct descendants from the primary MSZ. Rare Pd-dominated minerals (Pd-Hg ± As and Pd-Sb ± As) are considered to be neo-formations that probably formed from dispersed elements during supergene processes. Os-Ir-Ru alloy grains, present in the samples from the Umtebekwe River in the Shurugwi area, possibly originate from the Archean chromitite deposits of the Shurugwi greenstone belt and not from the Great Dyke. Geochemically, the Pt/Pd proportions increase from pristine via oxidized MSZ ores to the fluviatile environment, corroborating earlier findings that Pd is more mobile than Pt and is dispersed in the supergene environment. Detrital PGM can be expected to be present in rivers draining PGE-bearing layered intrusions, and economic placers may form under particular sedimentological conditions. Therefore, the work also highlights the fact that simple field methods have their value in mineral exploration, especially if they are combined with modern micro-analytical methods. Furthermore, it is established that the PGE-bismu thotel lurides, PGE-sulfarsenides, and PGE-oxides, dominating the PGM assemblages in the pristine and oxidized MSZ, are components that are unstable during weathering and mechanical transport. Including the genetically somewhat disputed Pt-Fe alloys, the order of decreasing stability in the supergene environment is as follows: (1) Pt-Fe and Os-Ir-Ru alloys (very stable) → (2) sperrylite (stable) → (3) cooperite/braggite (variably stable/"metastable") → (4) PGE-bismuthotellurides, PGE-sulfarsenides, and PGE-oxides (unstable).

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“…The braggite intergrowth suggests a secondary origin, although the chemistry of a precursor is difficult to constrain. It is known that cooperite is the highest-temperature Pt sulfide in the Bushveld reefs and it may be replaced or overgrown by later braggite at the late magmatic stage (Merkle and Verryn, 2003; Yudovskaya et al ., 2017). The Ni-rich braggite and vysotskite (Pd,Ni)S are not widespread in the Bushveld reefs, rather they are known to be formed under postmagmatic hydrothermal conditions, for example, in massive sulfides ores of the Noril'sk deposit (Genkin et al ., 1981).…”

Section: Resultsmentioning

confidence: 99%

Platinum-group minerals of the F and T zones, Waterberg Project, far northern Bushveld Complex: implication for the formation of the PGE mineralization

et al. 2018

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This study provides the first detailed mineralogical data on platinum-group element (PGE) mineralization of the Waterberg Project, in a previously unknown segment of the Bushveld Complex located in the Southern Marginal Zone of the Limpopo Belt. The lower ultramafic F zone is dominated by sperrylite (up to 82 area%) with minor Pt–Pd bismuthotellurides, Pd–Ni arsenides, Au–Ag alloy, Rh–Pt sulfoarsenides and rare Pt–Fe alloys. The upper more felsic-rich gabbroic T zone is dominated by Pt–Pd bismuthotellurides (up to 90 area%), Pd tellurides and Au–Ag alloy with rare sperrylite, braggite, Pd stannides and antimonides. The platinum-group minerals (PGM) of the F zone are associated mainly with magmatic base-metal sulfides (pyrrhotite, troilite, chalcopyrite and pentlandite), that have undergone alteration during significant serpentinization, accompanied by the formation of the secondary sulfide assemblage. The T zone in a leucogabbroic sequence contains relics of magmatic sulfides and is characterized by the development of the indicative chalcopyrite-millerite-pyrite assemblage, which is associated with widespread hydrothermal quartz and hydrous silicates (amphiboles, phlogopite, epidote and chlorite). The fluid-induced style of PGM remobilization, the high Au/PGE and the high proportion of native gold in the high-grade T zone ores in the magnetite-bearing leucogabbroic rocks are unique to the Bushveld Complex. The genesis of the T ores is interpreted as a result of primary PGE enrichment in the zone of interaction between the first influxes of the Upper Zone fertile melt and a resident gabbroic melt at the top of the Troctolite-Gabbronorite-Anorthosite (TGA) fractionated sequence with subsequent fluid remobilization. Whether the hydrothermal overprint facilitated the PGE sequestration in a favourable setting or dispersed the pre-existing magmatic concentrations along fluid pathways remains essentially unresolved at the current stage.

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Cooperite and braggite from the Bushveld Complex: implications for the miscibility gap and identification

Cited by 14 publications

References 45 publications

⁴⁰ Ar/ ³⁹ Ar age constraints on ore deposition and cooling of the Bushveld Complex, South Africa

⁴⁰ Ar/ ³⁹ Ar age constraints on ore deposition and cooling of the Bushveld Complex, South Africa

Detrital Platinum-Group Minerals in Rivers Draining the Great Dyke, Zimbabwe

Platinum-group minerals of the F and T zones, Waterberg Project, far northern Bushveld Complex: implication for the formation of the PGE mineralization

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Cooperite and braggite from the Bushveld Complex: implications for the miscibility gap and identification

Cited by 14 publications

References 45 publications

40 Ar/ 39 Ar age constraints on ore deposition and cooling of the Bushveld Complex, South Africa

40 Ar/ 39 Ar age constraints on ore deposition and cooling of the Bushveld Complex, South Africa

Detrital Platinum-Group Minerals in Rivers Draining the Great Dyke, Zimbabwe

Platinum-group minerals of the F and T zones, Waterberg Project, far northern Bushveld Complex: implication for the formation of the PGE mineralization

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⁴⁰ Ar/ ³⁹ Ar age constraints on ore deposition and cooling of the Bushveld Complex, South Africa

⁴⁰ Ar/ ³⁹ Ar age constraints on ore deposition and cooling of the Bushveld Complex, South Africa