Abstract
The Golden Mile deposit (1767 t Au) in the Archean Yilgarn Craton, Western Australia, is controlled by D2 strike-slip and D3 reverse faults displacing folded tholeiitic greenstones. Granodiorite and monzodiorite dykes emplaced into the faults predate and are synchronous with propylitic and sericite–ankerite alteration overprinted by the ore. Arsenopyrite and chlorite thermometry and fluid-inclusion data indicate ore formation at 420 ± 30 °C and 300 MPa and cooling to the ambient temperature at 10 km depth (250–300 °C). Fimiston refractory ore (7 g/t Au) in propylitic Golden Mile Dolerite is zoned from inner albite–ankerite to outer ankerite–phengite–quartz replacement. Pyrite–magnetite is overprinted by pyrite–hematite ± anhydrite. Arsenical pyrite encloses chalcopyrite, tennantite, gold and tellurides. Gold thio-sulfide complexes, buffered by magmatic SO2 and H2S in the fluid, were destabilised during the ankerite–pyrite replacement of propylitic chlorite, a reaction releasing hydrogen ions for the hydrolitic alteration of adjacent albite. Gold deposition was assisted by declining gold, silver, tellurium and sulfur solubility as the fluid cooled. Dissolved sulfate is recorded in pyrite by negative δ34S (− 10 to − 5‰) at magmatic Δ33S (0–0.2‰). Oroya ore bodies are subdivided into oxidised pyrite lodes (5 g/t Au) in propylitic GMD and reduced lodes (30–120 g/t Au) characterised by Stage 1 silica–pyrite and siderite–chlorite replacement in ankerite-rich wall rocks. Rapid cooling, an acidic fluid and the retrograde solubility of ankerite facilitated replacement and the deposition of minor arsenopyrite, pyrrhotite, chalcopyrite, sphalerite and gold. Locally, the H2S-rich fluid (log fS2 = − 5.8 ± 0.5 bar at 420 °C) was reduced by organic methane. Oroya Stage 2 ore fills crosscutting veins and cements breccia. Quartz, chalcedony, dolomite–ankerite, calcite, V-muscovite, V-chlorite and V-tourmaline form the gangue of pyrite–telluride ± magnetite ore. Altaite–tellurium myrmekites were deposited at ≥ 400 °C as melt droplets together with tellurantimony, altaite, calaverite, montbrayite and petzite. As fluid temperature and tellurium fugacity declined, free gold, krennerite, coloradoite and melonite also crystallised joined by sylvanite and hessite below 350 °C. Finally, trace covellite and digenite precipitated at high fluid sulfidation states.
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Introduction
The giant Golden Mile deposit at Kalgoorlie (1767 t Au to December 2018) is located in the Eastern Goldfields Province of the Archean Yilgarn Craton, Western Australia. Production is subdivided into underground (1893–1992, 105.6 Mt at 11.27 g/t Au) and open pit (1984–2018, 302 Mt at 1.91 g/t Au; Electronic supplementary material, ESM App. 1). The deposit and associated porphyry dykes occur in a zone of propylitic alteration more than 4.5 km long and 1 km wide at the surface, controlled by shear zones centred on the D2 Golden Mile strike-slip fault. Genetic models vary from magmatic–hydrothermal (Gustafson and Miller 1937; Mueller et al. 1988; Gauthier et al. 2007) to orogenic–hydrothermal invoking metamorphic fluid generated in the lower crust during fold-belt evolution (Goldfarb et al. 2005; Groves et al. 2016). Others regard the Golden Mile as a high-level, low-temperature deposit (300–170 °C) similar in style to epithermal Au–Ag deposits (Clout 1989; Shackleton et al. 2003; Voronin et al. 2017).
Structural, petrographic and geochemical studies of ore bodies (lodes) on levels of the Paringa South shaft, mined out during the recent open-pit operation, indicate formation by two hydrothermal systems (Mueller 2017, 2018; this issue). The Fimiston H2O–CO2 fluid was enriched in lithophile elements (Ca, Sr, K, Ba, Rb) and deposited auriferous pyrite ± anhydrite during the sericite–ankerite replacement of propylitic mafic rocks. Oroya-style mineralisation named after the D3 Oroya Shoot (> 62 t Au) overprints Fimiston ore in D2 strike-slip faults such as the Horseshoe No. 4 (> 200 t Au) and Phantom lodes but is the only ore in D3 reverse faults indicating a hiatus in hydrothermal activity. Oroya ore is characterised by an early As–Zn-rich pyrite stage and by a late Sb–Pb-rich sulfide–telluride stage marked by vanadian silicates and oxides. The Oroya H2O–CO2 fluid introduced silica, lithophile elements (Ca, Sr, K, Li, Rb) and, in contrast to the Fimiston fluid, siderophile Fe, Cr, Ni and V (Mueller 2018). The initial 87Sr/86Sr isotope ratios of tourmaline and scheelite (Mueller et al. 1991) and the stable isotope ratios of carbonates in the ore bodies and in the late-mineralisation Oroya kersantite dyke implicate the parent plutons of the local monzodiorite–granodiorite dykes as the fluid source (Mueller 2017; Mueller and Muhling 2019).
In this study, the mineralogy of Fimiston- and Oroya-style ore, based on 1360 electron-microprobe analyses, is summarised and interpreted to constrain the PTX conditions of gold deposition. The results indicate high fluid temperatures (420–300 °C) and pressure (300 MPa) corresponding to a deep crustal level (10 km) of ore formation and the cooling and reduction of oxidised magmatic fluids during wall-rock interaction. The similarities in magmatic association, alteration and mineralisation style to intrusion-related Cenozoic gold deposits are discussed with emphasis on the Porgera deposit in Papua New Guinea.
Geologic setting
The Kalgoorlie mining district is located in the Eastern Goldfields Province of the Yilgarn Craton (inset in Fig. 1), a continental-margin orogen characterised by 2.73–2.65 Ga greenstone belts. The stratigraphic, structural and magmatic–metamorphic evolution of the Kalgoorlie terrane is reviewed in Mueller et al. (2016, this issue). The lodes in the Golden Mile are confined to the tholeiitic Paringa Basalt (PB), the 600–750-m-thick Golden Mile Dolerite (GMD) and the basal carbonaceous part of the Black Flag greywacke. The differentiated GMD sill at the basalt–greywacke contact is dated at 2685 ± 5 Ma (zircon U–Pb; Tripp 2013) and subdivided into 10 petrographic units. The central Units 6 to 8 are attributed to a second pulse of iron-rich tholeiitic magma (Travis et al. 1971). The succession is folded into the Kalgoorlie Anticline and Syncline (D1) and metamorphosed to the actinolite–albite–zoisite greenschist facies. Igneous textures and pillow structures are well preserved. In Golden Mile Dolerite, augite is pseudomorphed by aggregates of tschermakite, actinolite and accessory chlorite, and calcic plagioclase by albite, zoisite and accessory epidote. Leuxoxene ± ilmenite lamellae outline former Ti-magnetite (Mueller 2017).
The Golden Mile deposit is controlled by the Boulder Lefroy-Golden Mile fault system (D2), which displaces the upright D1 folds 11–12 km in a left-lateral sense (Mueller 2007; Mueller et al. 2016). The steeply dipping shear zones are centred on the Golden Mile Fault and bounded by the Boulder Lefroy Fault in the southwest and by the Trafalgar Fault in the northeast (Fig. 1). Granodiorite porphyry dykes were emplaced into the strike-slip faults at 2676 ± 7 to 2671 ± 10 Ma after D1 metamorphism but prior to propylitic alteration. Barren sericite–ankerite ± chloritoid zones in the Golden Mile Fault, the Trafalgar Fault and at the GMD–PB contact of the Kalgoorlie Anticline (Fig. 1) and subsequent Fimiston ore formation are broadly synchronous with the intrusion of diorite dykes at 2663 ± 11 Ma (Gauthier et al. 2007). The ore bodies are ordered according to their host structure: D2a sinistral strike-slip faults (Fimiston system), D2b sinistral-reverse faults (Australia East system) and D3a reverse faults (Oroya Shoot system). Gold mineralisation took place when periods of D2 strike-slip reactivation alternated with D3a shortening. It ceased before the development of barren D3b thrusts (Mueller 2017).
Pre-sulfide hydrothermal alteration
In Golden Mile Dolerite, the ore bodies overprint propylitic assemblages. Metamorphic amphibole in augite sites is replaced by chlorite and minor Fe-calcite, and zoisite in plagioclase sites by calcite, albite and epidote again preserving the igneous texture. Metamorphic leucoxene is altered to rutile. Remnant primary Ti-magnetite is confined to GMD Units 6 and 7 (Travis et al. 1971; Bartram and McCall 1971). In Paringa Basalt, the ore bodies overprint sericite–ankerite assemblages in a contact zone about 150 m thick (Fig. 1). In this zone, part of the albite is replaced by microcrystalline quartz, muscovite and paragonite. Micron-sized rutile is evenly, whereas chlorite and magnetite are locally disseminated.
Ore bodies in the Paringa South mine
The Paringa South mine (Fig. 1) produced 4.0 Mt at 19.4 g/t Au (1893–1967) and 0.626 Mt at 4.36 g/t Au (1983–1987). The locations, structural setting, petrography and geochemistry of the ore bodies sampled are described in Mueller (1990, 2017, 2018). Gold mineralisation is subdivided into: (1) early Fimiston refractory pyrite ore; (2) Oroya Stage 1 ore characterised by pyrite + arsenopyrite ± pyrrhotite; and (3) Oroya Stage 2 ore characterised by vanadian muscovite, free native gold and tellurides. Fimiston ore is represented by the D2a Kelly Lode and B-Lode and by parts of the D2b Blatchford shear zone. Oroya-style ore is represented by the by the D2b Blatchford shear zone and vein and by the D3a Oroya Hanging Wall (OHW) Lode. The mineralogy of the Paringa South ore bodies is compared to data from the Horseshoe No. 4 Lode and from the high-grade Phantom Lode, both located close to the central Golden Mile Fault (ESM Fig. 1). The occurrence of enargite–famatinite and realgar in the No. 4 Lode and of copper sulfides in both ore bodies (see summary in ESM Fig. 1) constrains late-stage ore formation.
Analytical methods and terminology
Gangue and ore minerals in samples from the Paringa South lodes and from the D3a Flat Lode on the North Kalgurli shaft 13 level were examined in transmitted and reflected polarised light in 70 covered or polished thin sections and in 23 polished mounts. Selected sections and mounts were analysed by the senior author in the JEOL JXA-8530F field emission electron microprobe at the Centre for Microscopy, Characterization and Analysis (CMCA), the University of Western Australia. The averages and standard deviations of 768 wavelength dispersive (WDS) analyses of silicates, carbonates, phosphates and oxides and of 580 WDS analyses of sulfides, tellurides and native gold are listed in the Electronic supplementary material (ESM tables and appendices). Tiny inclusions (≤ 1 μm) of native gold and telluride in pyrite were imaged in backscattered electron (BSE) mode in a Verios 460 field emission scanning electron microscope (SEM). Energy-dispersive (EDS) analyses were carried out using the Oxford Instruments SDD detector and the AZtec database of standards. The inclusions were identified by molar ratio after eliminating the signals of the host pyrite. Instrument settings, calibration standards, detection limits and methods to estimate ferric iron are described in ESM Appendix 1.
Chlorite thermometry (error ± 50 °C) is based on the calibrations of Cathelineau (1988) and Lanari et al. (2014). The WDS microanalyses were recast using the software AX of Holland and Powell (2000), which allocates ferric iron by setting the total number of cations to 10 for 14 oxygens (Laird 1988). The results suggest that the iron in all chlorites is ferrous. The temperatures based on Lanari et al. (2014) are calculated at 200 and 300 MPa, the median isochore pressures of fluid inclusions in D3a reverse and D2a strike-slip faults, respectively (Ho et al. 1990). The chlorite data are complemented by arsenopyrite thermometry (details in ESM App. 1) using the calibration of Kretschmar and Scott (1976). The thermodynamic modelling of mineral equilibria at 300 MPa and elevated temperature (> 250 °C) was carried out using the software HCh (Shvarov 2008; Xing et al. 2019) and CHNOSZ (Dick 2008) and the thermodynamic datasets Unitherm (Shvarov 2008) and SUPCRTBL (Zimmer et al. 2016).
The term “silica” is applied to dense chert-like quartz, and “chalcedony” to microcrystalline quartz marked by local pores and fibrous crystals (Deer et al. 1992). The term “sericite” denotes white mica, “phengite” muscovite with IVSi > 3.1 and “paragonite” white mica with a ratio K/(K + Na) < 0.15 (International Mineralogical Association, IMA 1999; Fleet 2003). Carbonates of the dolomite–ankerite and magnesite–siderite solid-solution series are subdivided by their Fe/(Mg + Fe) ratio: dolomite < 0.2, ankerite 0.2 to 0.7 and siderite > 0.7 (Chang et al. 1998). Minerals in equilibrium contact are joined by hyphens or plus signs.
Mineralogy of Fimiston ore
The B-Lode on the Paringa South shaft 6 level consists of fault-fill veins surrounded by red albite–phengite–ankerite selvages grading into outer chloritic ankerite replacement in GMD Unit 4. Pyrite in the vein selvages (10 vol%) is in contact with magnetite and specular hematite (Mueller 2018). The Kelly Lode on 4 level was mapped at the southeast termination of this ore body. The array of fault-fill veins narrows and the pyrite-rich inner vein selvages decrease in abundance and width. They enclose remnant domains of propylitic GMD Unit 2 exposed in chlorite–calcite–albite facies below the lode. Magnetite and hematite are absent. The Blatchford Lode on 11 level crosscuts sericite–ankerite-altered Paringa Basalt. Fimiston ore in the S-C mylonite of the main shear zone is exposed 20 m northwest of the telluride extension vein mapped (Mueller 2018).
Quartz, albite and tourmaline
In Golden Mile Dolerite, the brittle veins are filled with granular quartz, albite, Fe-calcite and dolomite–ankerite (Fig. 2a). Fault-fill veins in major movement planes display brecciation and re-cementation (Fig. 6 in Mueller 2018). Quartz grain boundaries are sutured and partly lined with microcrystalline seams. In places, strained quartz crystals indicate extensional fibrous growth (Fig. 2b). Albite is marked by strained twin lamellae (Fig. 2c). Quartz and albite are pure except for trace iron (ESM App. 2).
Fine-grained quartz, albite and dolomite–ankerite are also major constituents in the vein selvages together with white mica and pyrite (Fig. 2a). The amount of albite decreases away from the vein. Chlorite (0.5 vol%) and tourmaline (1%) occur in contact with pyrite (Fig. 2d, e). The tourmaline classifies as dravite characterised by fluorine below detection, a low cation ratio Ca/(Ca + Na), low vacancy in the X-site (0.265), an average Fe/(Mg + Fe) ratio of 0.45 ± 0.03 (1σ) and ≤ 0.56 wt% V2O3 (ESM App. 2).
In the Kelly and B-Lode, an intermediate zone of feldspar-destructive hydrolytic alteration separates the albite-stable vein selvages from outer propylitic GMD, where albite is part of the pre-sulfide chlorite–calcite assemblage (ESM App. 2). In the hydrolytic zone, 0.5–1 m wide in the B-Lode (Fig. 4 in Mueller 2018), most albite is replaced by microcrystalline phengite + quartz, whereas the propylitic chlorite is replaced by ankerite, minor pyrite ± magnetite and newly formed chlorite (Fig. 2f).
Albite was not detected in the S-C mylonite of the Blatchford shear zone, which overprints pre-sulfide sericite–ankerite alteration in Paringa Basalt. Pinch-and-swell granular quartz–ankerite veins alternate with quartz–sericite, ankerite and pyrite–tourmaline seams (Fig. 10 in Mueller 2018).
Carbonate and apatite
Carbonates of the dolomite–ankerite series are major phases in the B-Lode and Kelly Lode and in the No. 4 Lode southwest of the Golden Mile Fault (Golding and Wilson 1983). The abundance of ankerite, phengite and pyrite in the outer hydrolytic zone defines the boundary of “lode alteration” to the older propylitic chlorite–calcite zone. Calcite (1–20 vol%) is present in the fault-fill veins, and fluor-apatite (0.5%) in vein selvages of the B-Lode (ESM App. 2). Many carbonate grains are zoned. In Fimiston ore lacking iron oxides, microprobe analyses and BSE images (Fig. 2g, h) show an increase in the cation ratio Fe/(Mg + Fe) with time, distinct in both the Blatchford (core 0.35, rim 0.57) and Kelly lodes (core 0.14, rim 0.29). The opposite trend is observed in the B-Lode, where ankerite crystallised together with magnetite and hematite (core 0.43; rim 0.36; ESM App. 3).
White mica and chlorite
Dioctahedral K-Na white mica (Ca < 0.008) varies in composition between alteration styles in the Paringa South mine (ESM App. 4). The outer part of the pre-sulfide contact zone in GMD Unit 1 is characterised by mixed-layer paragonite–muscovite ± phengite (Fig. 3a), whereas all ore bodies are characterised by muscovite and phengite (Fig. 3b). The ratio K/(K + Na) = 0.50 divides barren from mineralised alteration. The mica in GMD-hosted lodes, where albite is stable in the vein selvages, classifies mostly as K-rich phengite (IVSi > 3.1) charge-balanced by a component of ferro-alumino celadonite (Mg + Fe2+) at low contents of octahedral vanadium (VIV < 0.015; Fig. 3c). The allocation of ferric iron, based on cation stoichiometry (ESM App. 1), is high in B-Lode mica (Fe2O3 = 1.7–1.8 wt%) and lower in Kelly Lode mica (0.34%; ESM App. 4) correlating with the presence and absence of iron oxides, respectively. The white mica in Fimiston ore of the Blatchford shear zone, where albite is absent, is muscovite of distinctly lower K/(K + Na) ratio than in the GMD-hosted lodes (Fig. 3b). Its contents of octahedral Mg, Fe and V are low (Fig. 3c), and ferric iron was not allocated (ESM App. 4).
Chlorite is rare in the veins and vein selvages of the GMD-hosted lodes (Fig. 2d) and absent in Fimiston ore of the Blatchford shear zone. It is the main mineral in propylitic GMD Unit 2 below the Kelly Lode and minor (5 vol%) in the outer hydrolitic zone of the B-Lode, where it forms part of the ankerite–magnetite–pyrite replacement in augite sites of GMD Unit 4 (Mueller 2018). The chlorite analyses from these two localities (ESM App. 5) define a linear trend of increasing Fe/(Mg + Fe) and tetrahedral Al (Fig. 3d) determined by host-rock composition and by IVAl-temperature (Cathelineau 1988).
Rutile, magnetite and hematite
In propylitic Golden Mile Dolerite and in GMD-hosted Fimiston Lodes, rutile (1–3 vol%) replaces the ilmenite lamellae and rims of former Ti-magnetite (Fig. 4a). The rutile contains minor V2O3 (≤ 0.32 wt%) and FeO (ESM App. 6). In sericite–ankerite-altered Paringa Basalt, rutile forms anhedral or needle-shaped grains (2–15 μm), which line the foliation planes of the Blatchford shear zone (Mueller 2018).
Hydrothermal magnetite and hematite are present in the B-Lode. Disseminated sub- to euhedral magnetite (3 vol%) is partly replaced by hematite, in particular in the pyrite-rich selvages of the fault-fill veins. Early magnetite–pyrite gives way to late hematite–pyrite although all three minerals are locally in equilibrium contact (Fig. 4b). The V2O3 content of magnetite decreases away from the veins (0.34 to 0.12 wt%). Specular hematite contains V2O3 (0.51 wt%) and ilmenite in solid solution (8 mol%; ESM App. 6).
Fimiston sulfides and tellurides
Subhedral pyrite (5 μm to 1 mm) is the main sulfide in Fimiston ore (average 10 vol%). In the GMD-hosted lodes, most is disseminated in the replacement selvages adjacent to fault-fill veins (Fig. 2a). Arsenic substitutes for sulfur, and cobalt and nickel for iron in pyrite (ESM App. 7). Arsenic is below detection in Kelly Lode pyrite, but cobalt and nickel are enriched in the core of a few grains (≤ 0.71 wt% Co; ≤ 0.43% Ni). In the B-Lode, arsenic and cobalt increase laterally from the inner (< 0.05% As, 0.24% Co) to the outer replacement zone (≤ 0.78% As, 2.05% Co), where arsenical pyrite is in contact with tennantite and cobaltite (Fig. 4c; ESM Table 1). In the PB-hosted Blatchford shear zone, Fimiston-style pyrite forms seams along the S-C foliation (Fig. 4d). This pyrite is zoned from poikilitic arsenical cores (≤ 3.02% As) to solid As-poor rims (≤ 0.40% As). Cobalt is low (≤ 0.21% Co), and nickel below detection.
Native gold (1–40 μm) enclosed in or interstitial to pyrite has a fineness of 920 (13.8 at% Ag; normalised to 100% Au + Ag + Hg + Sb + Bi). Trace Hg, Bi and Te were detected in some grains (ESM Table 1). Most gold in Fimiston pyrite, however, occurs in submicron native grains (Fig. 4e) or in telluride inclusions (Fig. 4f). Petzite, coloradoite and melonite were identified in Kelly Lode pyrite, and petzite, hessite and coloradoite in B-Lode pyrite (ESM App. 8). The low Au/Ag ratio of B-Lode and Kelly Lode ore (0.43–0.72) suggests a predominance of petzite inclusions, whereas the ratio of bulk Fimiston ore (2.06) indicates that native gold and calaverite are most abundant (Mueller 2018). Chalcopyrite (0.1–0.5 vol%; Fig. 4a, c) is present in all Fimiston ore, whereas sphalerite is absent.
Mineralogy of Oroya ore
The Blatchford and OHW lodes replace barren sericite–ankerite-altered Paringa Basalt. In the D2b Blatchford Lode on the Paringa South shaft 11 level, Oroya-style mineralisation overprints Fimiston ore in the rise to the 1109 sublevel, where an extension vein branches off the main shear zone (Fig. 9 in Mueller 2018). Oroya Stage 1 pyrite–pyrrhotite ± arsenopyrite ore is present in the shear zone and in the outer part of the zoned vein, whereas Stage 2 telluride ore fills the central vein (120 g/t Au). The D3a Oroya Hanging Wall (OHW) Lode replaces altered basalt below the GMD contact at the SW-limb of the Kalgoorlie Anticline. On the Paringa South shaft 7 level, the lode is composed of mylonite and breccia containing Stage 1 pyrite–arsenopyrite ± pyrrhotite and Stage 2 telluride ore (48 g/t Au).
In contrast, the Flat Lode on the North Kalgurli shaft 13 level replaces propylitic GMD Unit 5 and occurs in a D3a reverse fault offsetting the steeply dipping D2a Lake View Lode. Massive Stage 1 siderite ± silica–chlorite fault fill is brecciated and cemented by Stage 2 (?) ankerite, minor siderite, chlorite and quartz. Early magnetite + pyrite is overprinted by hematite + pyrite. High-grade Au–Te–V ore is absent, and the refractory hematite–pyrite ore (5 g/t Au) is tentatively assigned to Stage 2.
Chalcedony, quartz and tourmaline
One of the characteristic features of Oroya ore is the abundance of Stage 1 chert-like quartz (silica) coloured grey by disseminated pyrite (Fig. 5a). Local pores and fibrous crystals in the outer zone of the Blatchford extension vein (Fig. 5b) suggest that the silica represents partly recrystallised chalcedony. In the shear zones, strain caused recrystallisation to a granular mosaic (Fig. 5c), local brecciation and cementation by siderite, chlorite and pyrite (Fig. 5d). Stage 2 comb-textured quartz and calcite crystals in the centre of the Blatchford extension vein are cemented by granular silica and minor carbonate. The quartz is pure except for trace FeO (0.2–0.5 wt%; ESM App. 2). Albite was not detected in the two basalt-hosted lodes but is a minor phase in veins of the Flat Lode (Mueller 2018).
Blue-grey or red-brown tourmaline is accessory (0.5–2 vol%) in Stage 1 ore of the Blatchford and Flat Lodes but is abundant (up to 20%) in the siliceous mylonite of the OHW Lode (Fig. 5e). The Stage 1 tourmaline classifies as schorl characterised by fluorine below detection, moderate vacancy in the X-site (0.309), an Fe/(Mg + Fe) ratio of 0.57 ± 0.05 (1σ), a low cation ratio Ca/(Ca + Na) and ≤ 0.54 wt% V2O3 (ESM App. 2). The Stage 2 tourmaline in the OHW Lode (Fig. 5f) classifies mostly as schorl given an Fe/(Mg + Fe) ratio of 0.53 ± 0.04 (1σ), but has higher fluorine (0.09 ± 0.07 wt%), more vacancies in the X-site (0.338) and higher vanadium contents (up to 1.16 wt% V2O3; ESM App. 2). Stage 2 tourmaline in the telluride-rich Oroya Shoot is bright ruby red (6.03–14.65% V2O3; Mueller and Muhling 2019).
Carbonates and apatite
Carbonates of the dolomite–ankerite series are major phases in both Oroya Stage 1 and Stage 2 gold ore, whereas siderite is characteristic of Stage 1. Calcite is abundant in Stage 2 fill of the Blatchford vein, and fluor-apatite (0.5 vol%) was detected in Stage 2 ore of the OHW Lode (ESM App. 2). Carbonate core–rim compositions (ESM App. 3) are quoted below as Fe/(Mg + Fe) cation ratios. In the oxidised Flat Lode, microcrystalline siderite in Stage 1 fault-fill is zoned from Fe-rich cores (0.81) to Mg-rich rims (0.60; Fig. 6a). The siderite is brecciated and locally replaced by chlorite, silica and pyrite-iron oxide assemblages (Fig. 6b). In the breccia cement, ankerite (0.49) is dominant.
In Stage 1 ore of the OHW Lode, siderite predominates over ankerite. Most siderite grains are weakly zoned (Fig. 6c). The ankerite is zoned from Mg-rich cores (0.37) to Fe-rich rims (0.48). In Stage 2 ore, siderite is accessory and ankerite predominant. Many grains are zoned from dolomite cores (0.17) to ankerite rims (0.40; Fig. 6d). In Stage 1 ore of the Blatchford shear zone, foliation-parallel veins are filled with granular quartz, Fe-calcite and ankerite. Fe-calcite partly replaces the fragments in fault breccia. Siderite and ankerite predominate in the Stage 1 silica replacement of both shear zone and vein. Most ankerite is zoned to Fe-rich rims. In Stage 2 ore of the vein, siderite is rare and calcite is most abundant (Fig. 6e). Calcite is zoned to Fe-rich rims, and dolomite (0.03) to ankerite rims (0.45; Fig. 6f).
White mica and chlorite
Dioctahedral K-Na white mica (Ca < 0.010) is minor in both Oroya Stage 1 and Stage 2 ore (5–10 vol%), less abundant than chlorite in the OHW Lode and about equally abundant in the Blatchford Lode. All Stage 1 and the majority of Stage 2 micas classify as muscovite (IVSi < 3.1; Fig. 3b) due to low levels of the Tschermak substitution [IVSi VI(Mg,Fe) = IVAl VIAl]. In the absence of albite, the mica K/(K + Na) ratios range from 0.55 to 0.95 (Fig. 3b). Seven analyses plot below the muscovite limit of 0.7 (IMA 1999) suggesting paragonite interlayers. On average, the Oroya muscovite lacks ferric iron and is more Na-rich than phengite in the GMD-hosted Fimiston Lodes (ESM App. 4). Compositional trends include the enrichment in potassium and vanadium from Stage 1 to Stage 2 (Fig. 3b, c). Trivalent vanadium substitutes for Al3+ (Fleet 2003) and fills up to one quarter of the octahedral sites (Fig. 3c), below the ideal composition of roscoelite (KV2AlSi3O10[OH]2; IMA 1999).
Chlorite is in contact with white mica and shares the trend in vanadium enrichment from Stage 1 to Stage 2. The pleochroism varies from pale yellow to brown-grey (Fig. 5d) or dark green (Fig. 6b) in Stage 1, and to pink (Fig. 5f) or orange-red in Stage 2. In the OHW Lode, chlorite forms stylolite seams in recrystallised silica. Relative to Fimiston B-Lode chlorites, the Stage 2 OHW and Blatchford chlorites are mostly higher in IVAl, whereas the Stage 1 chlorites are consistently higher (Fig. 3d) indicating high temperatures of crystallisation. The Flat Lode chlorites overlap in IVAl with B-Lode chlorites. In contrast, the Fe/(Mg + Fe) ratios of all Oroya chlorites vary widely illustrating the lack of temperature dependence and host-rock control (Fig. 3d). On average, IVAl in chlorite decreases from Stage 1 to Stage 2 in both the OHW and Blatchford Lode, whereas the Fe/(Mg + Fe) ratio increases (ESM App. 5).
Rutile, magnetite and hematite
Rutile is sparse in the extensional sections of D3a reverse faults (Flat Lode, OHW Lode) and in the Blatchford vein, where mineral fill resulted in the dilution of TiO2 inherited from the host rocks (Mueller 2018). Rutile trellis after Ti-magnetite is confined to thin muscovite–chlorite schist replacing GMD Unit 1 at the hanging wall contact of the OHW Lode. Micron-sized grains and needles line S-C foliation surfaces in basalt-hosted mylonite and cluster in the chalcedony zone of the Blatchford vein.
Magnetite– and hematite–pyrite aggregates occur in the Flat Lode, where they partly replace siderite fragments (Fig. 6b) adjacent to ankerite–chlorite–quartz cement. The magnetite (Fig. 7a) contains minor vanadium (0.21 wt% V2O3) and is locally zoned to low-V rims. Hematite replacing magnetite is enriched in vanadium (0.40% V2O3) but not in titanium. In contrast, late hematite in the breccia cement (Fig. 7b) contains 6 mol% ilmenite in solid solution (ESM App. 6).
Oroya Stage 1 sulfides and tellurides
The breccia ore of the Flat Lode (Stage 1 + 2?) contains about 5 vol% disseminated pyrite, many grains zoned (Fig. 7a) to poikilitic arsenical rims (≤ 1.97 wt% As; ESM App. 7). Chalcopyrite is accessory. Grains of native gold (< 1 to 15 μm) are attached to pyrite surfaces and enclosed in pyrite, commonly along growth zones lined with hematite (Fig. 7c). Some inclusions may be unidentified telluride. The gold is pure Au–Ag alloy and has a fineness of 909 (ESM Table 2). The Stage 1 gold in the Blatchford and OHW lodes has an average fineness of 895 but is alloyed with mercury (ESM Table 2). The silver (10.16–20.31 at%) and mercury contents (0.10–0.80 at%) vary from grain to grain.
OHW Lode
The mylonite and breccia ore contains pyrite (10–15 vol%) less than 5 μm to 3 mm in size. In chert-like quartz, subhedral grains and dendritic pyrite aggregates are associated and in contact with arsenopyrite and sphalerite (1 vol% each), lesser chalcopyrite and rare gersdorffite (Fig. 7d, e). Locally, euhedral arsenopyrite is enclosed in pyrite together with anhedral pyrrhotite (Fig. 7f). Native gold (< 1 to 32 μm) forms inclusions in pyrite and arsenopyrite (Fig. 7g), fills fractures in both together with melonite (Fig. 7h) and occurs attached to the surfaces of all sulfides.
The average pyrite is low in As, Ni and Co (< 0.12 wt%). A few grains have cores enriched in Ni (≤ 1.54%) and Co (≤ 0.42%), whereas others contain arsenical zones (≤ 0.83% As) in either core or rim (ESM App. 7). The sphalerite (average 1.88 at% Fe) encloses blebs of chalcopyrite. The chalcopyrite contains trace Co in solid solution and, locally, sphalerite and telluride inclusions (ESM App. 9). In arsenopyrite, Co and Ni are low (< 1 wt% combined) and Sb is below detection (ESM App. 10).
Blatchford Lode
The chert-like quartz in the Blatchford shear zone and the chalcedony margin of the extension vein contain pyrite (7–15 vol%) in contact with pyrrhotite (0.5–3%) and arsenopyrite (0.5%). The three phases form equilibrium assemblages (Fig. 8a) associated with native gold and melonite (Fig. 8b). Pyrrhotite has low average Co and Ni contents (0.06–0.12 wt%). Arsenopyrite is consistently enriched in Co (up to 4.02%), the cobalt content decreasing from core to rim in the shear zone but not in the vein. Micron-sized inclusions of gold and telluride were detected in both sulfides (ESM App. 10).
Pyrite–pyrrhotite contacts vary from mutual (in equilibrium) to embayed where pyrrhotite is replaced by finely granular pyrite (Fig. 8c, d) or by rare marcasite (Fig. 8e). Some aggregates are zoned from solid rims to granular cores (Fig. 8f) indicating the total replacement of early pyrrhotite. Pyrite also forms complex aggregates in chalcedony zoned from crystal cores to dendritic rims (Fig. 8g). On average, As, Ni and Co are low (< 0.3 wt%). Nickel is locally enriched (up to 1.69%; ESM App. 7).
Chalcopyrite and sphalerite (0.5 vol% each) are in contact with the iron sulfides (Fig. 8c). Rare ullmannite (Fig. 8h; ESM Table 1) occurs in veinlets adjacent to the main shear zone. Chalcopyrite contains Co in solid solution (< 0.08 wt%) and rare inclusions of sphalerite and native gold. Sphalerite in contact with pyrite or pyrite + pyrrhotite is rich in iron (5.21–5.73 at%) and encloses chalcopyrite blebs and micron-sized grains of gold telluride and bismuth sulfide (ESM App. 9).
Oroya Stage 2 sulfides and tellurides
On the Paringa South shaft 4 to 11 levels, Stage 2 sulfide–telluride ore (Au/Ag = 3.8–6.9) occurs in crosscutting breccia and vein networks in the OHW Lode and Oroya Shoot and in the Blatchford extension vein (Mueller 2018; Mueller and Muhling 2019). The OHW and Blatchford ore bodies contain subhedral pyrite (3–5 vol%), sphalerite, chalcopyrite and arsenopyrite (0.5% each). The sulfides are in contact with free gold and a Pb–Sb-rich suite of tellurides including montbrayite, calaverite, altaite, tellurantimony, coloradoite and minor petzite and melonite (ESM Table 2; App. 11). The pyrite contains inclusions of native gold and telluride, and adjacent free tellurides are in equilibrium contact with each other and with gold (Fig. 9a–e; ESM App. 12). Replacement textures are absent.
Stage 2 pyrite contains As (< 0.9 wt%) and Co (< 0.5%) in solid solution (ESM App. 7). Sphalerite associated with pyrrhotite in the Blatchford vein is more iron-rich (average 3.55 at% Fe) than Stage 2 sphalerite in the Oroya Shoot on the Paringa South shaft 4 level (1.92 at%), which is similar in composition to Stage 1 sphalerite in the OHW Lode on 7 level (1.88 at%; ESM App. 9). Chalcopyrite blebs and trace mercury are common in Stage 2 sphalerite, whereas most chalcopyrite is inclusion-free.
Tetrahedrite and digenite–covellite–bornite aggregates (0.1–0.2 vol%) are part of the assemblage in the Blatchford vein (Fig. 9f, g). Covellite and digenite also rim Stage 1 chalcopyrite in the OHW Lode adjacent to Stage 2 veins (Fig. 9h). The tetrahedrite has a low tennantite component (atomic ratio Sb/As = 43) and contains Fe, Zn and Ag in solid solution. Bi, Hg and Se were detected locally (ESM Table 1). Covellite and digenite both contain iron (0.76–3.90 wt%) substituting for copper, and covellite in the Blatchford vein contains minor silver (ESM Table 1).
Stage 2 native gold has an average fineness of 931 (11.9 at% Ag), but silver varies from grain to grain (6.5–18.3 at%). Other alloyed metals (Hg, Bi) and pyrite and telluride inclusions were detected locally (ESM Table 2). The principal gold telluride is montbrayite [mean: (Au21.81Sb1.19) (Te34.32Sb3.68); formula after Bindi et al. 2018] in contact with calaverite [(Au0.88Ag0.05Sb0.07)(Te1.88Sb0.12)] distinguished by its silver content (ESM Table 2; Fig. 9c–e). Petzite partly decomposed under the 20-nA electron beam of the microprobe resulting in non-stoichiometric WDS analyses (ESM Table 2). Under the low-energy beam used during EDS analysis, its composition was close to ideal (Ag3AuTe2; ESM App. 8). Tellurantimony (Sb2S3) always contains small amounts of lead in solid solution, and altaite (PbTe) and coloradoite (HgTe) incorporate minor antimony. Silver is locally present in all three (< 0.4 wt%; ESM App. 11). In melonite (NiTe2), minor Co and lesser Fe and Sb substitute for nickel (ESM Table 2).
Temperature–pressure estimates
Oroya Stage 1 arsenopyrite was analysed in two samples from the OHW Lode containing pyrite–arsenopyrite and pyrite–pyrrhotite–arsenopyrite assemblages. The average temperature calculated from 6 to 10 analyses (< 1 wt% Co + Ni + Sb) is remarkably consistent: 398 °C (2-phase), 392 °C (2-phase cores), 403 °C (2-phase rims), 408 °C (3-phase) and 410 °C (3-phase). The same consistency is evident in a sample from the Blatchford vein: 429 °C (2-phase), 432 °C (3-phase), 436 °C (3-phase cores) and 434 °C (3-phase rims). High-Co arsenopyrites (> 1 wt% Co ± Ni) give higher temperatures: OHW Lode 439 °C (2-phase), Blatchford Lode 448 °C (3-phase) and 455 °C (3-phase). In summary, the median temperature of 420 ± 30 °C is considered the most reliable estimate for Oroya Stage 1 ore (ESM Table 3).
Chlorite thermometry
Temperatures calculated according to Cathelineau (1988) for 8 to 20 chlorite grains per sample varied ± 12 to ± 32 °C (2σ) about the average. The wider spread of the Kelly Lode sample (± 48 °C), still within the error of calibration (± 50 °C; Lanari et al. 2014), is attributed to a mixture of remnant propylitic (340 °C) and ore-related chlorite in contact with pyrite (400 °C; ESM Table 3). Four samples taken across the OHW Lode allowed checks on consistency. Oroya Stage 1 chlorite (Mg number = 0.26–0.49) gave tightly grouped temperatures ranging from 409 ± 18 to 423 ± 20 °C (2σ precision). The temperature estimates based on Lanari et al. (2014) are outside the calibration range (> 500 °C) in two cases (ESM Table 3). In the OHW Lode, they are at odds with arsenopyrite thermometry. In the Flat Lode, they are too high to account for the low amount of ilmenite (6 mol%) in Ti-hematite (Braun and Raith 1985). Thus, the calibration of Cathelineau (1988) is preferred as it provides consistent estimates in agreement with arsenopyrite thermometry (ESM Table 3): 340 °C for propylitic alteration below the Kelly Lode, 370–400 °C for Fimiston ore in the Kelly and B-Lode, 385 ± 50 °C for late-stage Oroya ore in the Flat Lode, 400–420 °C for Oroya Stage 1 and 380–400 °C for Stage 2 ore in the OHW and Blatchford lodes.
Sulfide–telluride thermometry
Rare marcasite replacing pyrrhotite in Oroya Stage 1 ore of the Blatchford vein suggests temperatures < 425 °C (Qian et al. 2011). Stage 2 altaite–tellurium myrmekite in the Oroya Shoot on 4 level (Mueller and Muhling 2019) and in the Blatchford Lode on 10 level (Scantlebury 1983), interpreted to represent the solid-state exsolution of trapped melt, indicates deposition above the eutectic at 411 °C (Lin et al. 1989).
In the No. 4 and Phantom lodes (see ESM Fig. 1), the occurrence of krennerite suggests that many tellurides crystallised below 380 °C. The silver content of krennerite in the No. 4 Lode (3.1–6.2 wt%) agrees well with experimental values (3.3–6.2 ± 0.2%) at 380–350 °C (Cabri 1965). Sylvanite surrounding krennerite (Baker 1958) indicates cooling to below 350 °C (Cabri 1965). The presence of realgar crystals in the upper No. 4 Lode (< 760 m depth) and of Ag-rich covellite (Cu1.01–1.23Ag0.15–0.31S; Golding 1978) 1200 m below the surface suggest fluid cooling to < 310 °C. Realgar melts at 307 ± 5 °C, and covellite + argentites.s. melt incongruently at 325 ± 25 °C (Barton and Skinner 1979). The melting temperatures quoted, determined at 1 bar and dry conditions, increase with pressure by about 14 °C/kbar (Sharp et al. 1985), whereas aqueous fluid diffusing into immiscible melt will lower the solidus (Cabri 1965).
Pressure estimates
Barometry based on mineral assemblages in the Hannan South Cu–Au skarn 12 km southeast of Kalgoorlie provides an estimate of 440 ± 120 MPa (1σ) for replacement in D3 reverse faults (Mueller et al. 2012), a structural setting time equivalent to that of the Oroya ore bodies. Fluid inclusion data constrain the median and maximum isochore pressures to 280 and 400 MPa in D2a Fimiston Lodes and to 180 and 280 MPa in D3a Oroya Lodes (Ho et al. 1990). Fluid inclusions in Oroya-style hematite–pyrite ore from the North Kalgurli Flat Lode homogenised at maximum temperatures of 235–240 °C (Ho et al. 1990), 150 °C lower than estimated from chlorite thermometry (ESM Table 3). If this fluid was trapped as a single phase, the pressure calculated for the system H2O–CO2–NaCl would be 300 MPa at 350 °C and 380 MPa at 400 °C (ESM App. 13). The results suggest a pressure of at least 200 MPa, most probably 300 MPa for ore formation in the Golden Mile, corresponding to a depth of 7–11 km below the surface at lithostatic load (3.6 km per 100 MPa; Bucher and Frey 2002).
Discussion
The mineralogical and thermometric data presented above for representative ore bodies in the Golden Mile are summarised in Fig. 10. The pressure–temperature estimates are discussed first in comparison to those from other gold deposits, as they provide constraints on fluid composition (pH, oxygen, sulfur and tellurium fugacity) and fluid evolution during ore deposition. These constraints are integrated with those imposed by potential fluid sources, in particular the monzodiorite-suite plutons represented by porphyry dykes at Kalgoorlie (Mueller 2017; this issue). Key features of the Miocene Porgera gold deposit in Papua New Guinea are reviewed, as many are shared with the Golden Mile.
P–T regime of ore formation
The Golden Mile has been interpreted as an epithermal deposit (250–170 °C, 10–50 MPa; Clout 1989), especially with regard to the Oroya-style telluride ore (300–170 °C; Shackleton et al. 2003). Gauthier et al. (2007) also infer a “high crustal level (< 7 km and likely much shallower)” based on the occurrence of chalcedony and cockade breccia. In contrast, the results presented above indicate two superimposed hydrothermal systems (Fig. 10), peak fluid temperatures of 420 ± 30 °C, main-stage ore deposition from supercritical fluids at 400–350 °C, minor deposition during cooling to 300 °C and a mid-crustal level of mineralisation (7–11 km depth). Temperature estimates for other mesothermal gold deposits in the wider Kalgoorlie area are 420–250 °C (Mikucki and Ridley 1993), and 480 ± 60 °C for biotite–pyrite–anhydrite alteration at porphyry dykes below the East Repulse gold deposit (Bath et al. 2013). The presence of kyanite in some gold-related alteration zones indicates 250–400 MPa pressure and deep erosion since ore formation in the Eastern Goldfields fold belt (Mueller 2018).
Fluid composition and pH
The Fimiston and Oroya hydrothermal fluids were both of low to moderate salinity (1.0–5.5 wt% NaCleq), high density (0.75–0.95 g/cm3) and varied in mole fraction CO2 from 0.05 to 0.25 (median = 0.15). Methane (XCH4 = 0.02–0.06) was detected in veins where the D3a Oroya shear zones intersect altered carbonaceous greywacke (Ho et al. 1990). At 200–300 MPa pressure, ore deposition took place at supercritical conditions from fluids not separated into liquid and vapour (Fig. 11a).
The Fimiston Lodes are composed of Fe–dolomite–albite vein selvages, which grade into ankerite–phengite–quartz zones replacing propylitic Golden Mile Dolerite. Albite in the veins and selvages buffered the fluid pH to neutral values of 5 to 5.5, whereas the assemblage mica + quartz in the outer zone suggests more acidic pH values of 4–5 assuming 1–5 wt% NaCl in the fluid (Fig. 11b, c). In the outer zone, the hydrogen ions required to alter propylitic albite were released during the selective replacement of propylitic chlorite [Fe/(Fe + Mg) = 0.5] by ankerite [Fe/(Fe + Mg) = 0.3–0.4] and pyrite:
The Fe/(Mg + Fe) ratios of chlorite and ankerite, written in this simplified carbonation–sulfidation reaction for average Kelly and B-Lode compositions, vary with MgO and FeO in Units 1 to 10 of the GMD sill.
In the Oroya-style OHW and Blatchford Lodes, hosted by sericite–ankerite-altered Paringa Basalt, albite is rare or absent. The assemblage K-Na muscovite + quartz indicates a moderately acidic pH of about 4 for the input fluid (Fig. 11b, c). Minor late-stage albite in the Flat Lode and No. 4 Lode suggests an evolution to a near-neutral pH with time. The dissociation of H2CO3 (aqueous) had no effect (Fig. 11c).
Replacement silica
Chalcedony veins and replacement silica are common in epithermal Au–Ag deposits. The precipitation of chalcedony requires rapid cooling and super-saturation of silica in the fluid, conditions associated with boiling (Fournier 1985). Replacement silica–pyrite “jasperoid” is also widespread in Carlin-type gold deposits and is present in sericite alteration zones associated with intrusion-related Cu–Mo–Au deposits (Barton et al. 1997). In the Carlin-type deposits, jasperoid formed at 180–240 °C by carbonate dissolution and silica precipitation in sedimentary host rocks during the interaction with acidic, low-salinity (≤ 6 wt% NaCleq) H2O–CO2 fluids showing no evidence of boiling (Muntean 2018).
Chert-like quartz or chalcedony, dark grey due to enclosed pyrite, distinguishes Oroya- from Fimiston-style ore. In many Fimiston Lodes, chalcedonic quartz formed replacement zones (3.4–5.2 g/t Au) brecciated and cemented by light grey quartz + carbonate containing native gold and tellurides (Tomich 1952). These relationships are observed in the Paringa South mine and termed Oroya Stage 1 and Stage 2 (Fig. 10). Older hydrothermal ankerite in the Paringa Basalt contact zone and in Fimiston Lodes was replaced by chalcedonic quartz, a process promoted by an acidic pH and by the retrograde solubility of ankerite as the fluid infiltrated the wall rock and cooled (Fig. 11d). A slight super-saturation of silica and iron in the fluid is indicated by the presence of dendritic pyrite in chalcedony (Fig. 8a, g). Rapid cooling of the Stage 1 input fluid (420 ± 30 °C) was possible due to the low ambient temperature of the wall rocks, estimated at 250 °C at 10 km depth given a geothermal gradient of 25 °C/km in the greenstone belt (Mueller et al. 2016; this issue).
Fluid evolution from the source
The oxide–sulfide assemblages in Golden Mile ore (Fig. 10) have been interpreted to reflect the infiltration of a reduced metamorphic fluid (Goldfarb et al. 2005) oxidised by reaction with Ti-magnetite in the Golden Mile Dolerite sill (Evans et al. 2006). The destruction of the magnetite component during greenschist-facies metamorphism and propylitic alteration prior to ore deposition and the low amount of remnant Ti-magnetite (< 1 vol%) relative to ferrous chlorite (40–50 vol%) available to buffer the fluid are inconsistent with this interpretation. Alternatively, the oxidised fluids were sourced from I-type plutons in the composite batholiths emplaced into the Kalgoorlie Terrane. In the Archean Wyoming Province, USA, calc-alkaline intrusions in the Louis Lake batholith released low-salinity H2O–CO2 and high-salinity aqueous fluids at crystallisation pressures > 300 MPa, which formed lode gold deposits and copper-rich veins in the adjacent greenstone belt (Vaughn and Ridley 2014).
As argued in other contributions to this issue, mass-balance calculations, strontium isotope and stable isotope data implicate the parent plutons of the monzodiorite-suite stocks and dykes emplaced along the Boulder Lefroy–Golden Mile fault system as the source of the auriferous fluids. Hornblende compositions indicate that the I-type calc-alkaline melts had high water contents (3–6 wt% H2O) and oxidation states (log fO2 = − 11.3 to − 12.8 at 750–850 °C). In log fO2–T space, these constraints place the intrusions on the isomolar SO2–H2S buffer curve (Fig. 12a), consistent with the sulfate in apatite (0.14–0.37 wt% SO3), which suggests trace igneous anhydrite (Mueller et al. 2016). Fluid exsolved from such melts may have positive bulk δ34S values of up to 5‰ (Manalo et al. 2018) and evolve along the SO2–H2S buffer to sulfur contents of 0.1 to 0.01 wt% at 500–400 °C (1 to 0.1 mol ΣS; Ohmoto 1986).
The Hannan South Cu–Au endoskarn southeast of Kalgoorlie formed from such a magmatic fluid, which became reduced by interaction with the porphyry wall rocks as it cooled and moved away from its source (Fig. 12a). In the Golden Mile, the late hematite–pyrite ore in the Fimiston-style B-Lode and in the Oroya-style Flat Lode may record the oxidation state of the input fluids, because this ore was deposited after most interaction with chlorite in the GMD host rock had ceased. Organic methane released from carbonaceous greywacke and interflow shales (Simpson 1912) and trapped in fault zones (Blatchford, OHW, No. 4 lodes) caused a sharp reduction of the Oroya Stage 1 H2O–CO2 fluid stabilising pyrrhotite at oxygen fugacities trending towards the CO2–CH4 buffer (Fig. 12a). Again, this effect waned with time and the Oroya Stage 2 fluid was mainly buffered by pyrite + magnetite, the oxidation state increasing in the No. 4 Lode during the deposition of late hematite (Fig. 12a).
Fluid oxidation–sulfidation state during mineralisation
The oxidation–sulfidation state of the aqueous–carbonic fluids during mineralisation is constrained by the iron sulfide–iron oxide assemblages observed and by the ferrous iron in dolomite–ankerite and siderite, the most abundant gangue minerals. Thermodynamic calculations indicate that the ferroan dolomite–calcite assemblage, present in fault-fill veins of the Kelly Lode (Fimiston), Blatchford shear zone (Oroya Stage 1) and Blatchford vein (Oroya Stage 2), is stable at 420 °C (Fig. 12b). The stability of iron-rich carbonates increases sharply at lower temperature (Fig. 12c). Consequently, siderite and ankerite predominate in the chalcedony “chill” zone of the Blatchford vein and in the carbonate–chlorite cement of silica breccia in the OHW Lode (both Oroya Stage 1). The common zonation of carbonates to iron-rich rims is probably also due to the decline of temperature with time. However, the reverse zonation to Mg-rich rims coincident with hematite + pyrite in the Fimiston-style B-Lode and the Oroya-style Flat Lode suggests a competing effect related to the increased oxidation state of the fluid.
In Fimiston-style ore, ankerite is much more abundant than siderite because the Fimiston fluid introduced calcium but not iron (Mueller 2018). During wall-rock infiltration, ankerite compositions were controlled by the Fe/(Mg + Fe) ratio of the propylitic chlorite replaced, by the co-precipitation of pyrite ± magnetite and finally by declining temperature. The phase relations indicate that calcite + Fe-dolomite remained stable relative to anhydrite during high-T pyrite–magnetite mineralisation and that ankerite + anhydrite were stable during lower-T pyrite + hematite, when chlorite replacement ceased and the oxidation state was buffered by H2S–HSO4− in the input fluid (Fig. 12b, c).
The Oroya fluid introduced both calcium and iron (Mueller 2018) precipitating siderite + ankerite in variable proportions. In the Blatchford, OHW and parts of the No. 4 Lode, the Stage 1 high-T assemblage pyrite–pyrrhotite was deposited during fluid reduction by organic methane. Pyrrhotite became unstable when the fluid cooled and was partly replaced by pyrite during the deposition of siderite + ankerite. In Stage 2 ore, the presence of early pyrite + magnetite (Phantom Lode) and of late hematite and pyrite + gypsum (No. 4 Lode) indicate an oxidation state close to that of the input fluid (Fig. 12).
Fluid oxidation state and sulfur isotopes
Sulfur isotope analyses of pyrite from major Fimiston Lodes gave δ34S values of − 5.8 ± 2.2‰ (n = 34; Golding et al. 1990). Anhydrite in Fimiston breccia ore has δ34S values of + 12.0 to + 19.2‰ (n = 7; Clout et al. 1990). Pyrite from the B-Lode and Kelly Lode has values of − 7.82 ± 1.32‰ (1σ, n = 5) and − 9.23 ± 1.41‰ (1σ, n = 15; ESM in Godefroy-Rodriguez et al. 2018). The Δ33S values in pyrite from these two lodes are tightly grouped at 0.18 ± 0.03‰ (1σ, n = 20), consistent with an I-type magmatic origin for sulfur (Xue et al. 2013). In Oroya ore, δ34S values of − 3.4 ± 4.6‰ (n = 22) were detected in pyrite from the oxidised Flat Lode (Golding et al. 1990), whereas the values of pyrite in the reduced Blatchford shear zone are positive and grouped into δ34S = 0.47–1.32‰ (n = 5) and δ34S = 13.76–23.51‰ (n = 2). The Δ33S values (0.55 ± 0.12‰, 1σ, n = 7) of both groups indicate a contribution of black shale sulfur (Godefroy-Rodriguez et al. 2018).
The temperature-dependent δ34S fractionation between sulfide and sulfate deposited from an evolved magmatic fluid with an initial bulk δ34S of 2 ± 1‰ and molar SO2–H2S = 1 has been modelled by Rye (1993) taking into account the disproportionation of SO2 at about 400 °C according to the reaction:
The magnitude of δ34S fractionation suggests that much of the pyrite in the Fimiston Lodes and in the Flat Lode was deposited from fluids containing dissolved sulfate given temperatures of 400–350 °C (ESM Fig. 2). The pyrite analyses from pyrrhotite-bearing assemblages in the Oroya Stage 1 Blatchford shear zone show a wide spread of positive δ34S values. The lower range of δ34S = 0.47–1.32‰ may be close to the bulk sulfur δ34S of the input fluid. The upper range of δ34S = 13.76–23.51‰ cannot be explained by pyrite–sulfate fractionation at 400 °C (ESM Fig. 2) and may represent sulfur mobilised by the thermochemical reduction of Fimiston anhydrite, a reaction catalysed by methane:
Constraints on sulfide deposition
Estimates of sulfur fugacity in the Oroya Stage 1 ore fluid forming the Blatchford and OHW lodes are based on the arsenopyrite–pyrite–pyrrhotite assemblages analysed (ESM Table 3) and on the iron content of sphalerite (Fig. 13a). When combined, these methods provide a range of log fS2 (− 5.3 to − 6.6 bar). There are no independent estimates for Fimiston Lodes. Fluid evolution in the ore bodies is shown schematically in a standard log fS2–T diagram, constrained by sulfidation reactions and assuming an initial log fS2 = − 5.8 ± 0.5 bar for all fluids at a peak temperature of 420 ± 30 °C (grey field in Fig. 13b).
Many Fimiston Lodes (arrow F in Fig. 13b) display a simple fluid evolution path at an intermediate sulfidation state to coexisting hematite + pyrite + tennantite (red field) at lower temperature. The fluid cooling implied is consistent with the lateral zonation in the B-Lode, where As-poor pyrite + chalcopyrite dominate in the inner albite–ankerite zone, and As-rich pyrite + tennantite + chalcopyrite in the outer ankerite–phengite–quartz zone. A similar cooling path probably applies to the Oroya-style Flat Lode.
The assemblage pyrite–arsenopyrite–pyrrhotite (blue field) indicates a low to intermediate sulfidation state for the Oroya Stage 1 fluid in the reduced OHW and Blatchford lodes, whereas pyrite + chalcopyrite + tetrahedrite suggest a higher sulfur fugacity for the Oroya Stage 2 fluid (green field). In the No. 4 Lode (magenta arrow), the Oroya Stage 2 fluid remained largely in the tetrahedrite stability field but crossed temporarily into that of enargite–famatinite, before sulfur fugacity and temperature decreased during the deposition of realgar and rare native arsenic. Post-telluride deposition, the Stage 2 fluid became depleted in most metals and evolved to a high sulfidation state in the sense of Einaudi et al. (2003) precipitating trace bornite, digenite and covellite (violet arrow and field in Fig. 13b).
Constraints on telluride deposition
Myrmekitic aggregates of altaite + native tellurium in Oroya Stage 2 ore on the Paringa South shaft 4 and 10 levels (Mueller and Muhling 2019) represent immiscible melt droplets deposited at high fluid temperature (> 400 °C) and tellurium fugacity (Fig. 13c). The Stage 2 ore in the OHW and Blatchford lodes on levels 7 and 11 does not contain native tellurium, and myrmekite is absent except for limited calaverite–petzite exsolution (Fig. 9d). Altaite, tellurantimony, calaverite and, probably, montbrayite and petzite were deposited at about 400 °C when tellurium fugacity remained above the calaverite–gold boundary, constrained in sulfur fugacity by the pyrrhotite–pyrite phase boundary and by the absence of stibnite and galena (grey field in Fig. 13c). As the fluid cooled to 350 °C, deposition of the above tellurides continued but was accompanied by that of native gold, coloradoite and melonite (Fig. 13d). In the No. 4 and Phantom lodes, late-stage hessite and sylvanite were deposited at 350–300 °C when tellurium fugacity declined further. The absence of galena and stibnite in the OHW and Blatchford lodes and their rarity in the No. 4 and Phantom lodes suggest a rapid depletion of lead and antimony in the Stage 2 fluid due to the early crystallisation of altaite, tellurantimony and tetrahedrite. The high Au/Ag ratio (3.8–6.9) of Oroya Stage 2 ore in the Paringa South mine relative to such ore in the No. 4 Lode (Au/Ag = 1.4) reflects silver under-saturation in the fluid at 400–350 °C, and increasing Ag–telluride deposition during cooling to 300 °C. Hessite–sylvanite myrmekite in the Phantom Lode (Baker 1958) is interpreted to have formed from a high-T phase by solid-state exsolution at 170 °C during terrane uplift (see Cabri 1965).
Gold transport and deposition
Previous studies of Archean ore fluids have emphasised the role of the Au (HS)2− complex in transport, and the role of wall-rock sulfidation as the main depositional mechanism (Mikucki and Groves 1990; Mikucki 1998; Goldfarb et al. 2005). These conclusions are re-examined in the light of the pressure estimate (300 MPa) and temperature range (420–300 °C) for ore formation established in this study.
In the case of the refractory Fimiston ore, our fluid modelling confirms the dominant role of gold thio-sulfide complexes in transport (Fig. 14) and of wall-rock sulfidation in the precipitation of auriferous pyrite. During fluid infiltration, ankerite + pyrite replaced chlorite and phengite + quartz replaced albite in propylitic Golden Mile Dolerite, a process approximated by the reaction:
Assuming a high oxidation state and neutral pH for the Fimiston input fluid, the modelling indicates steep declines in the solubility of gold, silver, tellurium and sulfur from 420 to 350 °C, suggesting that fluid cooling aided gold and telluride deposition during pyrite growth. While H2S(aq) was the dominant sulfur species in the fluid, significant amounts of sulfate were present at T > 350 °C (Fig. 14).
These conclusions also apply to the refractory pyrite ore of the oxidised Oroya-style Flat Lode formed by fault-fill and replacement of propylitic GMD. The free-milling Oroya-style ore in the other lodes (OHW, Blatchford, No. 4, Phantom) replaced rocks previously altered to ankerite-rich assemblages thus excluding wall-rock carbonation–sulfidation as the principal cause of gold precipitation. Assuming reduced and acidic fluid conditions during ore deposition, the modelling indicates lower gold and tellurium solubility relative to a “Flat Lode input fluid”, slightly higher silver and sulfur solubility, and an absence of dissolved sulfate (Fig. 14). Fluid cooling from 420 to 300 °C and reduction are regarded as the main mechanisms for gold, sulfide and telluride deposition.
The tellurium solubilities predicted are low (< 1 ppm). The thermodynamic properties are extrapolated from room temperature in the case of telluride and poly-telluride complexes and from experiments at < 350 °C for tellurite oxy-complexes (McPhail 1995; Grundler et al. 2013). However, the stability of poly-telluride complexes (probably Te22−) has been established experimentally to 600 °C and 80 MPa (Brugger et al. 2012) suggesting that the predictions are reasonable.
Comparison to Cenozoic gold deposits
The Golden Mile has been interpreted as an orogenic gold deposit formed in faulted greenstones from reduced metamorphic fluids generated in the lower continental crust during fold-belt evolution (Goldfarb et al. 2005; Groves et al. 2016). A challenge to this genetic model is the V-rich Oroya-style Au–Ag–Te ore, which accounts for 250–350 t of the total gold produced but is absent in most other orogenic deposits. The progression from early sulfide- to late telluride-rich ore is common in Cenozoic Au–Ag–Te deposits (Afifi et al. 1988b), an evolution recognised as Stage 1 and 2 in Oroya-style ore.
The Cenozoic deposit selected for comparison is Porgera in Papua New Guinea (651 t Au to 2018; ESM App. 1). The deposit is centred on hornblende–feldspar porphyry stocks marking a 5-km-wide magnetic anomaly interpreted as the source pluton (Richards 1990). The stocks were emplaced at 6 Ma into Cretaceous black siltstones of the Central Range, a 1300-km-long fold and thrust belt formed by the collision of the Australian continent with an island arc terrane 8 Ma ago (van Ufford and Cloos 2005). Apatite fission track ages constrain the onset of orogenic uplift at the mine to 4–5 Ma suggesting that 3–4 km of crust was eroded at a minimum rate of 0.7 km/Ma (Weiland and Cloos 1996). The stocks vary from alkali olivine gabbro to hornblende–biotite monzodiorite (Richards 1990; nomenclature after Wimmenauer 1985). The mafic phenocrysts (Mg-hastingsite > diopsidic augite) in monzodiorite have a sodic component (2–7 mol%) and are zoned from Cr–Ni-rich cores to Ti-rich rims. Alkaline indicator minerals are absent but the whole-rock Nb/Y ratios (3.3–4.5) suggest an alkaline component. K2O (1.15–2.27 wt%), Cr (6–170 ppm), Ni (8–59 ppm) and V (197–292 ppm) are enriched. The hybrid calc-alkaline/alkaline magmas are interpreted as sourced from metasomatised mantle lherzolite (Richards 1990).
The 40Ar/39Ar ages of magmatic biotite, hydrothermal biotite and roscoelite average 5.95 ± 0.17 Ma (Ronacher et al. 2002). Early alteration in monzodiorite includes sub-solidus albitisation of groundmass feldspar and a pervasive propylitic overprint (Richards 1990; Richards and Kerrich 1993). Subsequent gold-related alteration styles include (1) early calcite–magnetite veins with actinolite–biotite selvages and accessory chalcopyrite, pyrrhotite and pyrite; (2) main-stage “Waruwari” calcite–siderite–quartz veins, texture-destructive sericite–dolomite replacement, disseminated arsenical pyrite, vein-fill pyrite, sphalerite, galena and tetrahedrite; and (3) late-stage breccia and veins controlled by the Roamane fault zone, cemented and filled with chalcedony, quartz, roscoelite (29–30 wt% V2O3), calcite, dolomite, anhydrite, hematite, pyrite, chalcopyrite, tetrahedrite, gold, calaverite, krennerite, petzite, hessite, coloradoite and altaite (Richards and Kerrich 1993; Ronacher et al. 2004). Pre-mining grades were as follows: Waruwari refractory pyrite ore at 3.6 g/t Au + 14.4 g/t Ag and Roamane ore at 6 g/t Au + 9 g/t Ag including Au–Te–V ore at 35 g/t Au + 55 g/t Ag. All ore was low in base metals (0.04–0.4%; Fleming et al. 1986).
The aqueous fluids (0.1–3.1 mol% CO2) trapped in vein quartz were of moderate salinity (4–10 wt% NaCleq) and density (0.52 g/cm3). Saline (16–32 wt% NaCleq) and vapour-rich fluid inclusions were rare. Fluid temperatures are estimated at 350–450 °C during early propylitic and actinolite–biotite alteration, 300–350 °C during main-stage sericite–dolomite alteration and 140–260 °C during late silica–roscoelite fault-fill assuming 30–45 MPa pressure (Richards and Kerrich 1993; Richards et al. 1997; Ronacher et al. 2000, 2002, 2004). The sulfur isotope ratios of pyrite from propylitic and sericitic alteration (δ34S = 1.4–5.2‰) suggest deposition from reduced magmatic fluids (bulk δ34S = 4‰), whereas those of pyrite (δ34S = − 14.0 to − 11.4‰) and anhydrite (δ34S = 20.6–22.2‰) in Au–Te ore indicate oxidising conditions. Other isotope data (δ18O, δD, δ13C) support a magmatic fluid source for the early refractory ore and fluid mixing with groundwater during late Au–Te–V mineralisation in the Roamane Fault (Richards and Kerrich 1993).
Summary and conclusions
The key results of previous contributions to the Golden Mile thematic issue, mainly those related to ore bodies in the Paringa South mine, are integrated with the conclusions drawn from this study to provide a summary for comparison with the Porgera case history.
- 1.
The Golden Mile deposit (1893–2018: 1767 t Au) is located in the Eastern Goldfields Province of the Yilgarn Craton, a continental-margin orogen characterised by 2.73–2.60 Ga granite–greenstone terranes including the Kalgoorlie ultramafic–mafic volcanic rift and the Kurnalpi andesite arc.
- 2.
Deformation at 2680–2640 Ma took place in phases as the far-field principal stress changed from an ENE–WSW direction during D1 and D3 folding, first to the southeast during sinistral transcurrent faulting (D2), and later to the northeast during dextral faulting (D4). Such a dynamic regime is recorded in the Andean continental margin caused by periods of orthogonal and oblique subduction.
- 3.
The deposit is controlled by the D2 Boulder Lefroy–Golden Mile fault system (> 2200 t Au). Extensive shear-zone networks of Riedel geometry formed in the Golden Mile when kilometer-scale sinistral strike-slip on the master faults strained folded GMD and PB. At 2675 Ma, granodiorite porphyry dykes were emplaced into the shear zones after D1 greenschist-facies metamorphism but prior to hydrothermal activity.
- 4.
At 2665–2645 Ma, I-type hornblende monzodiorite and granodiorite stock–dyke complexes were emplaced into the D2 fault system in spatial association with kersantite dykes, Cu–Au skarns and mesothermal gold deposits. The calc-alkaline intrusions are enriched in lithophile (K, Rb, Li, Sr) and siderophile elements (Mg, Cr, Ni, V), a signature attributed to the melting of metasomatised mantle peridotite. Sub-solidus albitisation of plagioclase is widespread. Hornblende and apatite compositions indicate that the melts were water-rich (5–6 wt% H2O), oxidised (δNNO + 1.0 to + 2.4 log units) and anhydrite bearing. The isotope composition (δ13CPDB = − 3.0 to − 2.2‰, δ18OSMOW = 8.3 to 9.7‰) of the magmatic H2O–CO2 fluids released is constrained by data from Cu–Au skarn, the Oroya kersantite dyke and local monzodiorite–granodiorite stocks.
- 5.
In the Golden Mile, magmatic–hydrothermal fluids infiltrated the reactivated D2 fault system during the emplacement of monzodiorite porphyry dykes, generating kilometer-scale zones of pre-sulfide chlorite–calcite–epidote and sericite–ankerite ± chloritoid alteration centred on the master faults and the GMD–PB contact in the D1 Kalgoorlie Anticline. Fimiston-style ore was deposited in D2 faults during post-porphyry sinistral strike-slip (≤ 30 m offset at granodiorite dykes). Oroya-style ore associated with late kersantite dykes overprints Fimiston ore in many D2 faults but is the only ore type in D3 reverse faults, which displace the older structures up to 50 m indicating a hiatus in hydrothermal activity.
- 6.
The Fimiston and Oroya hydrothermal fluids were aqueous–carbonic (XCO2 = 0.15), low to moderate in salinity (1.0–5.5 wt% NaCleq) but of high density (0.75–0.95 g/cm3), trapped in quartz at a lithostatic pressure of 300 MPa (3 kbar) at 10 km crustal depth. The calculated fluid oxygen isotope ratios (8.2 to 9.8‰) are consistent with I-type magmatic water, but the carbon isotope ratios are 13C-enriched (δ13CPDB = − 1.7 to − 0.5‰), perhaps due to the partial reduction of CO2 to CH4 by fluid interaction with ferrous greenstones close to the source intrusions. Such a source is indicated by the initial 87Sr/86Sr ratios of scheelite, tourmaline and anhydrite (0.7013–0.7018), which match those of monzodiorite porphyry and kersantite (0.7014–0.7018) but are higher than those of the tholeiitic host rocks (0.7009–0.7011).
- 7.
Fimiston ore bodies (7.0 g/t Au, Au/Ag = 3.1, Cu + Zn + Pb < 0.05 wt%) in propylitic GMD account for 80–85% of the total gold. They are zoned from albite–ankerite selvages on fault-fill veins to outer hydrolytic ankerite–phengite–quartz replacement. Early pyrite + magnetite is overprinted by pyrite + hematite ± anhydrite. Much of the pyrite is arsenical, associated with chalcopyrite and tennantite, and contains submicron inclusions of native gold and tellurides. Mass balances indicate that the ore fluid introduced K, Ca, CO2, S, Ba, Rb, Cs and Sr but not iron suggesting a felsic (granodiorite?) source.
- 8.
Chlorite thermometry indicates that the Fimiston-style ore formed at 400–350 °C, well above the ambient temperature in the greenstone belt (about 250 °C). The fault-focussed ore fluid, buffered in oxidation state by magmatic SO2 and H2S, interacted with propylitic chlorite in the wall rock by carbonation and sulfidation. Gold was deposited in pyrite due to the destabilisation of gold thio-sulfide, a process assisted by the decline in gold, silver, tellurium and sulfur solubility as the fluid cooled. The alteration of chlorite to ankerite + pyrite at the replacement front released hydrogen ions for the synchronous alteration of propylitic albite to phengite + quartz. When wall-rock interaction waned, hematite and anhydrite were deposited, recorded in pyrite by negative δ34S values (− 10 to − 5‰).
- 9.
Oroya ore bodies are subdivided into the oxidised Flat Lode (late pyrite–hematite), characterised by refractory ore (5 g/t Au) in propylitic GMD, and reduced lodes (30–120 g/t Au, Au/Ag = 1.4–6.9, Cu + Zn + Pb < 0.1 wt%, V ≤ 0.24%) such as the Oroya Shoot (> 62 t Au). Oroya-style ore is characterised by Stage 1 chalcedonic silica–siderite–chlorite replacement of ankerite-rich wall rocks, and As–Zn-rich sulfide ore composed of pyrite (15 vol%), minor pyrrhotite, arsenopyrite, sphalerite, chalcopyrite and free gold. Stage 2 ore is composed of pyrite (5%), minor magnetite, tetrahedrite, native gold and an Sb–Pb-rich suite of tellurides and sulfosalts. The ore fluid introduced silica and iron and lesser Mg, Mn, Ca, K, CO2, S, Te, Li, Rb, Sr, W, Cr, Ni and V suggesting a mafic (monzodiorite?) source.
- 10.
Arsenopyrite and chlorite thermometry indicate that the Oroya fluid infiltrated reactivated D2 faults and early D3 faults at 420 ± 30 °C and cooled to 300 °C, the magnitude of cooling constrained by late realgar. Rapid cooling, an acidic fluid and the retrograde solubility of wall-rock ankerite facilitated Stage 1 chalcedony–pyrite replacement and the subsequent deposition of siderite + chlorite (at 350 °C). In some faults, the ore fluid was reduced by trapped organic methane stabilising pyrite + pyrrhotite and acting as a catalyst in the dissolution of Fimiston anhydrite (pyrite δ34S = + 13.8 to + 23.5‰). Fluid interaction with carbonaceous greywacke and shale is indicated by a component of sedimentary sulfur in Stage 1 pyrite (Δ33S = 0.5‰). The sulfur fugacity of the H2S-rich fluid is estimated at log fS2 = − 5.8 ± 0.5 bar (at 420 °C) based on arsenopyrite and sphalerite compositions.
- 11.
Oroya Stage 2 Au–Te ore fills veins and cements breccia crosscutting Stage 1 replacement. Quartz, chalcedony, dolomite–ankerite, calcite, V-muscovite (≤ 14 wt% V2O3), V-tourmaline and V-chlorite form the gangue of pyrite–telluride ± magnetite ± nolanite ore. Myrmekitic altaite–tellurium aggregates trapped as Pb–Te (Au–Ag) melt droplets were deposited at ≥ 400 °C together with free grains of altaite, tellurantimony, calaverite and, probably, montbrayite and petzite. As fluid temperature and tellurium fugacity declined, grains of native gold, krennerite, coloradoite and melonite also crystallised, joined by sylvanite and hessite below about 350 °C. After telluride mineralisation, the fluid evolved to a high sulfidation state (log fS2 = − 5 bar at 300 °C) depositing trace bornite and covellite + digenite.
The Archean Golden Mile and the Miocene Porgera gold deposits share the plate-tectonic setting and the relation to mantle-derived monzodiorite-suite intrusions, a fluid source responsible for the distinctive Te–V signature of late high-grade ore. They differ in the depth of formation, 10 versus 3–4 km below the surface, the difference in pressure (300 versus ≤ 100 MPa) evident in the higher CO2 content (XCO2 = 0.15) and density (0.75–0.95 g/cm3) of the Golden Mile fluids relative to those at Porgera (XCO2 ≤ 0.03; 0.52 g/cm3). In both deposits, the bulk of the gold was deposited at 450–300 °C in refractory pyrite during the carbonation–sulfidation of propylitic chlorite in the wall rocks. Cooling due to groundwater influx into the Roamane Fault at Porgera was not replicated in the deeper Golden Mile, where silica replacement formed at 10 km depth in ankerite-rich rocks due to the temperature difference between fluid and wall rock (≥ 150 °C) and the retrograde solubility of ankerite. In both deposits, late-stage pyrite–hematite ± anhydrite assemblages closely reflect the oxidation–sulfidation state of the magmatic input fluid.
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Acknowledgements
The senior author is grateful to Greg Hall and Patrick Verbeek for allowing access to the Paringa South underground mine in 1986–1987; Marco Einaudi for sharing his knowledge on magmatic–hydrothermal ore deposits during post-doctoral studies at Stanford University in 1992–1994; the staff of Kalgoorlie Consolidated Gold Mines for guided tours in 2016; the Geological Survey of Western Australia for access to the Joe Lord core library in 2016 and 2019; and the staff of the Western Australian Museum for access to their mineral collection. Malcolm Roberts acknowledges the support from the Centre for Microscopy, Characterization and Analysis (CMCA) at the University of Western Australia.
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Mueller, A.G., Hagemann, S.G., Brugger, J. et al. Early Fimiston and late Oroya Au–Te ore, Paringa South mine, Golden Mile, Kalgoorlie: 4. Mineralogical and thermodynamic constraints on gold deposition by magmatic fluids at 420–300 °C and 300 MPa. Miner Deposita 55, 767–796 (2020). https://doi.org/10.1007/s00126-019-00939-8
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DOI: https://doi.org/10.1007/s00126-019-00939-8