Abstract
Stibnite was mined until the end of the twentieth century in the Schlaining ore district, Austria, near the easternmost border of the Eastern Alps where windows of Penninic ophiolites and metasediments are exposed below Austroalpine tectonic units. In Early Miocene, structurally controlled small vein and metasomatic stibnite-quartz deposits were formed in Penninic Mesozoic calcareous marbles and calcite schists. Fluid inclusion studies identified two fluids involved in the mineralization: (i) a low-salinity, low-CO2 metamorphic fluid that precipitated quartz at approximately 240 °C and (ii) a stibnite-forming ore fluid that had a meteoric origin. There is no evidence of boiling or that the fluids mixed during mineralization. The ore components Sb and H2S were leached by fluid/rock interaction from buried rock units. Stibnite mineralization occurred by cooling the ore fluid to below 300 °C, at less than 2000 m depth. Quartz precipitated at slightly lower temperatures, approximately contemporaneous with stibnite. Fluid migration and ore deposition are probably related to high heat flow during the exhumation of the Rechnitz Window in response to Neogene extension and/or shallow Early Miocene andesitic magmatism. The study emphasizes that data obtained from the analyses of gangue minerals alone cannot routinely be used to infer the origin and depositional conditions of the associated ore minerals.
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Introduction
Hydrothermal stibnite (principal ore mineral of Sb) deposits occur in different mineralization styles and settings. Low-sulfidation epithermal vein-type deposits, hot spring deposits, some porphyry and molybdenum deposits, parts of orogenic gold or sediment-hosted Carlin-type gold deposits, sediment-hosted hydrothermal quartz-stibnite veins, some SEDEX-type deposits, or massive metasomatic carbonate replacement deposits are examples. In some deposits, stibnite mineralization is also associated with considerable concentrations of gold, mercury, silver, tin, tungsten, or base metals (e.g., Gumiel and Arribas 1987; Dill 1993, 1998; Peng et al. 2002; Wagner and Boyce 2003; Hagemann and Lüders 2003; Fan et al. 2004; Liu and Ye 2005; Yang et al. 2006; Buchholz et al. 2007; Bortnikov et al. 2010; Pohl, 2020).
Stibnite deposits have been mined worldwide from various geological settings, among which the carbonate replacement deposits (especially with high Au grades) have been the most economically important. Today, most of the world’s Sb production comes from China (about 78%), followed by Bolivia, Russia, South Africa, and Tajikistan. Sb is predominantly produced from epithermal gold-antimony deposits and/or carbonate replacement deposits. For example, the largest stibnite ore deposit in the world, the giant carbonate-replacement Xikuangshan deposit in China, has an average ore grade of about 4% Sb and contains total Sb metal reserves of about 2,500,000 metric tons (e.g., Fu et al. 2020).
Stibnite was mined in the ore belts of the Rhenohercynian, Saxothurigian, and Moldanubian Zones in Western and Central Europe but also in SE Europe and in the Eastern Alps (Fig. 1). The last active stibnite mining in Europe ceased at the end of the twentieth century. The samples studied here originate from the Schlaining mining district, which is located at the very end of the Eastern Alps in the small Rechnitz ophiolite window (Burgenland, Austria). The former underground mining district comprises two areas, namely the Kurt and the Neustift ore districts (Fig. 2), where stibnite was mined in several pits until the closure of the last mine in 1990. The total production from strata-bound and vein-type stibnite mineralization over more than 200 years was about 1,000,000 tons of crude ore with an average Sb grade of about 5% (Weber 1989), making Schlaining one of the most important antimony producers in Europe.
The origin and age of the unique Alpine stibnite deposit at Schlaining have provoked some debate and controversy. The proposed models have invoked synorogenic ore formation (e.g., Maucher and Höll 1968; Petrascheck 1978; Nawaratne 1989), epithermal ore formation due to hydrothermal activity triggered by Miocene andesitic volcanism in the Pannonian Basin (e.g., Hiessleitner 1947; Belocky et al. 1991; Pohl and Belocky 1994), or ore deposition due to Neogene fault-related fluid migration (Grum et al. 1992; Dunkl et al. 1998).
Here, we address the origin and formation of the former economic stibnite mineralization in the Schlaining mining district using conventional and near-infrared (IR) light microscopy, bulk analyses of cation and anion content, and δ2H, δ18O, and noble gas isotope ratios of fluid inclusions hosted in quartz and stibnite from strata-bound vein-type Sb ores.
Geological setting
The Upper and Middle Austro-Alpine units of the Eastern Alps host a variety of mostly strata-bound sub-economic polymetallic ore deposits which belong to the so-called Sb-W-Hg formation according to Maucher and Höll (1968). The most important stibnite deposits were mined in the Rabant Sb-(As, Au, Cu, Pb) district located in the southern part of the Kreuzeck mountain group (Fig. 1). The genesis of these Sb-accentuated deposits has been unclear for many years. For example, Höll (1978) related the Sb mineralization to the Upper Ordovician to Silurian hydrothermal activity triggered by submarine volcanism. In contrast, detailed studies of some Ag-(Au)-base metal deposits in the southern part of the Kreuzeck mountains have shown that these deposits were structurally controlled and probably related to fluid migration during the late Paleogene rather than Paleozoic hydrothermal events (Feitzinger et al. 1995). Thus, the early Paleozoic age for the strata-bound Sb-rich mineralization in the Eastern Alps as proposed by Höll (1978) is unlikely (W. Paar, pers. comm.).
The strata-bound, partly vein-type quartz-stibnite mineralization of the Schlaining mining district differs from the Sb-(As, Au, Cu, Pb) mineralization of the Eastern Alps by the absence of W, Au, Ag, Hg, base metal ores, S isotope values, and age. The mineralization is hosted by Mesozoic metamorphic rocks of the Rechnitz Window at the very end of the Eastern Alps (Fig. 1). The rocks of the Rechnitz group belong to the Penninic calc-mica schists (Bündnerschiefer) series of the Upper Schieferhülle and consist of mafic, ultramafic, and metasedimentary rocks (Schmid 1956). The Rechnitz Window is bordered by rocks of the older Austroalpine unit and sediments of the Tertiary and Quaternary ages (Fig. 1).
Three metamorphic events are recorded in the rocks of the Rechnitz group: (I) ophiolite formation at temperatures exceeding 750 °C (Koller 1985) due to local oceanic hydrothermal activity with low spreading rates, (II) 65 ± 6 Ma-old subduction-related HP/LT metamorphism at temperatures of 330 to 370 °C and pressures of 6 to 8 kbar (Koller 1985), and (III) late Alpine greenschist metamorphism at temperatures between 350 and 430 °C and pressures up to 3 kbar (Koller 1985; Hoinkes et al. 1999; Dunkl and Koller 2001). The rocks of the Rechnitz group were rapidly exhumed during the earliest Miocene. K/Ar dating of white mica from the western part of the Rechnitz Window yielded ages between 22 and 19 Ma (data compilation in Dunkl 1992), which are similar to zircon fission track ages of 21.9 and 13.4 Ma (Dunkl 1992; Dunkl and Demény 1997). This age range overlaps that of the opening of the Pannonian Basin (21 to 15 Ma) related to the lateral escape of the Eastern Alps and Carpathian rollback subduction (Favaro et al. 2015). The age of the Schlaining stibnite mineralization is assumed to be between 19 and 17 Ma and thus coeval with the Tertiary faulting of the area (Belocky et al. 1991; Grum et al. 1992; Dunkl et al. 1998).
According to Lehnert-Thiel (1967), Belocky et al. (1991) and Grum et al. (1992), the mineralization in the Schlaining mining district can be divided into three mineralization stages. Minor early-stage mineralization comprises pyrite, marcasite, arsenopyrite, sphalerite, and quartz. The subsequent main mineralization stage is nearly mono-mineralic, consisting of very pure stibnite with only trace amounts of other metals, with quartz and minor carbonate as gangue minerals (Lehnert-Thiel 1967; Grum et al. 1992). Trace ore minerals besides the massive stibnite are pyrite, sphalerite, and arsenopyrite. Minor late stage mineralization is polymetallic and contains cinnabar, fahlore, chalcopyrite, sphalerite, and stibnite (Lehnert-Thiel 1967; Belocky et al. 1991; Grum et al. 1992). Gangue minerals of this stage are calcite, ankerite, and quartz.
In the Neustift ore district (Fig. 2), massive stibnite mineralization occurs as a strata-bound ore layer hosted by 50–80-m-thick dark gray chalk and/or mid-Cretaceous calcareous mica schists (Bauer 1966; Schönlaub 1973) directly below the contact to chlorite-rich greenschists. In the Kurt district (Fig. 2), strata-bound Sb mineralization was less abundant, and stibnite was mostly found in four WNW-ESE striking, steep parallel veins (Pollak 1953, 1955; Bauer 1966). The veins are irregularly formed, and there are metasomatic replacement and barren zones. Locally, fluid injected from the veins into bedding plane fissures hosted by calcite marble and greenschists and caused silicification of the rocks (Pollak 1953, 1955).
Methods
For this study, samples of massive stibnite (16,066, 16,070, HUB in Table 1) and stibnite-quartz specimens (16,064, 16,065, WL in Table 1) from the Schlaining antimony deposit were used.
Fluid inclusion microthermometry
Microthermometric measurements of fluid inclusions hosted in quartz from the stibnite mineralization were conducted using a Fluid Inc. USGS heating/freezing system mounted on a BX 50 Olympus microscope. Fluid inclusions in stibnite were studied using a Linkam heating/freezing stage (THMS600 system) coupled to an Olympus BH2 UMA-IR infrared microscope with a × 50 IR objective and a InGaAs IR camera that allows observation in the near-infrared region between λ = 800 and 1800 nm (Lüders 2017). The InGaAs IR camera also allows observations of phase changes during microthermometric runs at the lowest light intensity of the used IR microscope (Lüders 2017). Thus, any analytical artifacts resulting from the heating of the samples by IR light (Moritz 2006; Peng et al. 2020) can be excluded. Both heating and freezing stages were calibrated with synthetic fluid inclusion standards supplied by Synflinc. Fluid properties were calculated using the HOKIEFLINCS_H2O-NACL Microsoft Excel spreadsheet (Steele-MacInnis et al. 2012).
Laser Raman spectroscopy
The vapor bubbles of aqueous two-phase fluid inclusions hosted in quartz were analyzed for gas content (CO2, N2, H2S, CH4) using a LabRAM HR Evolution (Horiba Jobin YvonTechnology) instrument at an excitation wavelength of 532 nm (green laser). For internal calibration, silicon (520 cm−1) was used. Raman spectra of gases in fluid inclusions were acquired in the spectral range between 1200 and 3000 cm−1. A 3 × 30 s acquisition time was used for the measurements of aqueous inclusions.
Bulk crush-leach analysis
Bulk crush-leach analysis of fluid inclusions was carried out at the University of Leeds following the methodology described in detail by Banks et al. (2000). In total, 3 samples of quartz and 5 samples of stibnite were chosen for the analysis. All samples were carefully inspected for fluid inclusion abundances (primary, pseudo-secondary, secondary fluid inclusions) prior to analysis. One stibnite sample (WL) hosts abundant secondary fluid inclusions that are arranged along trails in large stibnite crystals. Primary fluid inclusions are less frequent in this sample.
Samples of quartz and stibnite were crushed to 1–2-mm grain size and cleaned by boiling several times in 18.2 ΜΩ water and dried prior to the analysis. Approximately 0.5 to 1 g of purified sample material was manually crushed with an agate mortar and pestle. The resulting mineral powder was leached with 18.2 ΜΩ water and filtered through a 0.2-μm Nylon filter prior to the analysis. Ion chromatography was used for the analysis of the anions Cl−, Br−, and SO42− in the leachate solutions. The cations Na+, K+, and Li+ were measured using flame emission spectroscopy. The detection limits for the elements analyzed are as follows: Na = 20 ppb, K = 25 ppb, Li = 1 ppb, Cl = 20 ppb, and Br = 1 ppb. With an average precision, as determined from a series of replicate analyses, of better than 10% relative standard deviation.
Isotope analyses
In total, 16 samples of quartz and stibnite were analyzed to determine the δ2H and δ18O values of the fluid inclusion water. Part of the samples used for the isotope analysis was the same as used for crush-leach analysis and fluid inclusion microthermometry. The samples were analyzed by two distinct techniques at the Max Planck Institute for Chemistry in Mainz. Both techniques allow for online sample analysis but work on fundamentally different continuous flow analyzers. One technique uses an isotope ratio mass spectrometer (IRMS) that is connected to a mechanical crushing unit. The analytical line uses a cold trap to collect fluid inclusion water that is released from crushing. When heating the cold trap, the sample water is liberated and passes through a pyrolysis furnace, where it is thermally separated into H2 and CO gas, which can separately be measured in the IRMS. The other technique couples an online mechanical crushing unit to a cavity ring-down spectroscope (CRDS). The analytical setup runs on a nitrogen carrier gas that is moisturized by a standard water to remove memory effects from which the instrument suffers when run with a dry carrier gas. Fluid inclusion water released by crushing a sample is measured on top of the standard water background. Isotope values can then be calculated by subtracting the standard water background from the sample peaks. The technical specifications, methodology, and calculation protocols of both analytical lines are explained in detail in de Graaf et al. (2020a).
The 18O/16O ratios of the quartz samples were measured using the Potsdam large geometry CAMECA 1280-HR SIMS according to the method proposed by Ramsey and Wiedenbeck (2018).
Noble gas analysis was performed using samples of 0.32 to 1.9 g of hand-picked quartz and stibnite mineral separates. The samples were loaded into an ultrahigh-vacuum spindle crusher, which was pumped at room temperature for at least 24 h to remove the atmospheric gases adsorbed on grain surfaces. For gas extraction, the samples were crushed under vacuum, and the gases released were admitted to the preparation line. Water was frozen in a dry ice-cooled trap, and other chemically active species were removed in Ti sponge and ZrAl getters. The noble gases were then separated from each other in a cryogenic adsorber, and noble gas concentrations and isotopic compositions were determined in a VG5400 noble gas mass spectrometer according to the procedures described by Niedermann et al. (1997).
Results
Stibnite-quartz relationship
Host rocks in contact with the stibnite mineralization are hydrothermally altered and intensively silicified (Fig. 3a), which was thought to indicate an epigenetic origin (e.g., Chovan et al. 2002). Locally, the host calcareous mica schists are impregnated by diffuse stibnite mineralization extending a few centimeters into the country rocks (Fig. 3b). Chemical analysis of calcareous schists near the contact with the stibnite veins that lack visible Sb mineralization has Sb and As concentrations between 24–47 and 11–78 ppm, respectively. The Pb concentrations are less than 3 ppm, and Zn concentrations are between 37 and 97 ppm in the studied samples.
Euhedral stibnite crystals that precipitated in open spaces (Fig. 3c) in the veins are striated and, in some cases, fractured due to syn- and/or post-depositional deformation (Fig. 3d). Quartz commonly penetrates stibnite (Lehnert-Thiel 1967; Belocky et al. 1991; Fig. 3e), and locally, the long prismatic quartz crystals are etched along their margins by stibnite which -together with stibnite infilling the interstices between grains (Fig. 3f) -suggests cogenetic precipitation of quartz and stibnite.
Fluid inclusion petrography and microthermometry
Stibnite samples from the Schlaining district have excellent transparency in near-infrared light as was observed for stibnite from other localities (e.g., Lüders 1996, 2017; Bailly et al. 2000; Shimizu 2018; Krolop et al. 2019). The stibnite crystals are typically striated in the direction of growth. Primary two-phase (L + V), aqueous fluid inclusions are elongated, occasionally as negative crystals oriented parallel to {110} or {010} (Fig. 4a-c). The orientation of pseudo-secondary fluid inclusions in stibnite is also crystallographically controlled, as trails are frequently oriented perpendicular to {110} or {010}.
Secondary fluid inclusions are almost absent in the studied stibnite samples, except for sample WL which contains numerous, obvious secondary fluid inclusion trails that cut the margins of stibnite crystals (Fig. 4d). In general, secondary fluid inclusions are much smaller compared to primary inclusions (Fig. 4a-d).
Quartz associated with stibnite typically forms crusts of small crystals growing on the stibnite crystals or as infillings between crystals. There are abundant aqueous two-phase fluid inclusions and often fragments of stibnite incorporated during quartz crystallization. Primary aqueous two-phase fluid inclusions are located on growth zones (Fig. 4e) or are arranged in three-dimensional clusters and/or parallel crystal planes. The inclusions have elongated, negative crystal or rounded forms (Fig. 4f). Secondary aqueous two-phase fluid inclusions are also abundant in quartz occurring in trails along the healed fractures. Due to the high abundance of fluid inclusions in some quartz samples, it was often difficult or even impossible to determine clear age relationships between the fluid inclusion assemblages. Secondary modifications of fluid inclusions due to necking-down were also observed in some cases.
Visible CO2-bearing fluid inclusions were rarely observed in calcite samples from the main mineralization stage (Belocky et al. 1991) and are absent in stibnite and quartz. However, low CO2 concentrations and, in some cases, traces of CH4 were detected by Raman spectroscopy in the gas bubbles of two-phase fluid inclusions (Fig. 5). Melting of clathrate was not observed during freezing/heating, indicating that the quartz-forming fluid was not saturated with respect to CO2. Other gases such as N2 or H2S were not detected by laser Raman spectroscopy.
During freezing runs, it was not possible to determine the first melting of ice in stibnite-hosted fluid inclusions. The final melting of ice in primary stibnite-hosted inclusions was measured between − 4.5 and − 3.5 °C, corresponding to salinities of 5.7 to 7.2 wt.% NaCl equiv. (Bodnar 1993) with the homogenization temperatures in a narrow range between 240 and 250 °C (Fig. 6). Pseudo-secondary fluid inclusions in stibnite have salinities similar to or only slightly lower than the primary fluid inclusions but have lower homogenization temperatures (Fig. 6). Secondary stibnite-hosted fluid inclusions have significantly lower salinities and homogenization temperatures which are similar to fluid inclusions in quartz (Fig. 6). The latter shows the first melting of ice between − 11.1 and − 10.6 °C, which is close to the eutectic temperature of the pure H2O-KCl system. The final melting temperatures of fluid inclusions in quartz were measured between − 2.0 and − 1.7 °C indicating salinities between 2.9 and 3.4 wt.% NaCl equiv. (Fig. 6). Homogenization temperatures of fluid inclusions in quartz are also lower than those of primary fluid inclusions in stibnite and are between 198 and 208 °C (Fig. 6).
Crush-leach analyses
The concentrations of anions and cations in stibnite- and quartz-hosted fluid inclusions released by crushing are plotted in Na–K-Cl-Br diagrams (Fig. 7). Fluid inclusions in quartz have Cl/Br molar ratios similar or slightly lower than seawater whereas stibnite-hosted fluid inclusions (except the WL sample which contains abundant secondary fluid inclusions) have higher Br concentrations, thus having considerably lower Cl/Br ratios. Fluids that do not lie on the seawater evaporation line have experienced water–rock interaction (WRI), where Na in the fluid has been exchanged for another cation, and therefore plot to the left of the evaporation line as indicated in Fig. 7a. For example, Na may be depleted in the fluid through exchange with Ca in plagioclase (Davisson and Criss 1996) or through albitization of K-feldspar (Banks et al. 2002; Möller et al. 2017). Here, the majority of samples plot on or within error of the seawater evaporation line (Fig. 7a). However, since WRI does not affect the concentrations of chloride and bromide or their ratio in solution (e.g., Fontes and Matray 1993), the different Cl/Br of fluid inclusions in quartz and stibnite suggest the fluids had different sources.
As observed for Br, there is also a difference in the K contents of fluid inclusions hosted in stibnite and quartz. The Na/K ratios of fluid inclusions in quartz are higher than those in stibnite-hosted fluid inclusions (Fig. 7b). However, in the Na/K vs. Cl/Br diagram (Fig. 7b), fluid inclusions in both quartz and stibnite show K enrichment relative to seawater, suggesting that Na–K exchange reactions between fluids and minerals were an important process in the fluid evolution.
Fluid inclusion isotope data
Inclusion fluid isotope data were acquired from 10 stibnite samples and 6 quartz samples using IRMS and CRDS techniques with the analyses showing a good level of reproducibility between them. A complete overview of fluid inclusion water isotope analyses is presented in Table 1 and Fig. 8. Fluid inclusions in quartz have the highest isotope values, ranging from 5.6 to 12.3‰ for δ18Owater and − 34.3 to − 24.9‰ for δ2Hwater. In contrast, stibnite has consistently lower values ranging from − 6.0 to 5.9‰ for δ18Owater and always below − 40‰ for δ2Hwater. The lowest isotope values are recorded in the WL stibnite sample, which hosts abundant secondary fluid inclusions. Fluid inclusion water in stibnite and quartz from the Schlaining district plots in isotopically distinct fields in Fig. 8, suggesting different fluid sources for quartz and stibnite.
The δ18O ratio of the original quartz-forming fluid is uncertain, since in situ oxygen isotope re-equilibration between fluid inclusion water and quartz may cause a decrease in δ18Owater ratios after deposition (e.g., Rye and O’Neil 1968; Taylor 1997). SIMS analyses of oxygen isotope ratios in three quartz samples yielded δ18Oquartz values between 23.7 and 26.9‰. Using a mean δ18Oquartz value of 25.9‰ and a temperature of 270 °C (Belocky et al. 1991), a δ18Owater value of ca. 17.3‰ for the quartz-forming fluid can be calculated with the equation of Clayton et al. (1972). This calculated δ18Owater value is higher than the δ18Owater values measured in quartz samples and suggests that the latter may not represent the original values of the fluid (de Graaf et al. 2020b).
This study describes the first application of a CRDS system for fluid inclusion isotope analysis on vein-type deposits (de Graaf et al. 2020a). It has been argued that contaminant gases released during crushing, which may be especially abundant in vein minerals, could possibly interfere with measurements on CRDS instruments (Arienzo et al. 2013). In contrast, the cold trap procedure in the IRMS setups flushes through non-water gas before the analysis of the sample water. The good reproducibility between the IRMS and CRDS techniques thus indicates either that contaminant gases have a minor interference on the CRDS system or that there is a general scarcity of interfering gas in the samples. The successful analysis could be made on the CRDS system down to 0.03 µl, which is well below the commonly reported analytical size limitations of generally 0.1 to 0.2 µl for fluid inclusion isotope analytical systems. This demonstrates the potential of CRDS systems for measuring small amounts of fluid inclusion water.
The isotopic and elemental abundances of noble gases in Schlaining quartz and stibnite fluid inclusions are presented in Table 1. Two quartz samples have 3He/4He ratios consistent with the atmosphere (1 Ra = 1.39 × 10−6) within their rather large error limits, which are due to the low He concentrations. 4He/20Ne and 20Ne/36Ar ratios are also air-like for WL quartz, but distinctly higher (~ 3 times atmospheric) for quartz sample 16,064. The third quartz sample 16,065 has a 3He/4He ratio of (0.45 ± 0.14) Ra at 4He/20Ne more than 20 times atmospheric, indicating a mixture of predominantly crustal He (~ 0.02 Ra; Ballentine and Burnard 2002) with a few percent of mantle He (~ 6.1 Ra; Gautheron and Moreira 2002).
The 4He/20Ne ratios of the stibnite samples are 80–500 times above the atmospheric value, at air-like 20Ne/36Ar (Table 1). Therefore, the atmospheric He contribution is negligible for all of them, and again, the 3He/4He ratios of ~ 0.1–0.3 Ra likely reflect a mixture of crustal He with ~ 2–4% mantle He. This is illustrated in Fig. 9, showing 3He/4He vs. 4He/20Ne ratios. All data, regardless of the mineral type, plot at about equal relative distances from the air-crust and air-mantle mixing lines, indicating that mantle He contributions are similar in all of them. The obvious difference is the contribution of atmospheric He, which is considerably higher for the quartz samples than for the stibnite samples.
In addition to the atmospheric He contribution, the 4He/40Ar* ratio (where 40Ar* is the non-atmospheric 40Ar fraction) is also completely different for quartz and stibnite. In stibnite-hosted fluid inclusions, it is within the range of crustal or mantle production ratios (~ 4–53; cf. Ballentine and Burnard 2002), whereas in quartz-hosted fluid inclusions, it is lower by three orders of magnitude (0.003–0.007). This indicates that stibnite trapped essentially original fluids with no (or only minor) fractionation between He and Ar, while the fluids trapped by the quartz had already lost the majority of the He fraction at the time of fluid entrapment.
Discussion
Microthermometric measurements of fluid inclusions hosted in stibnite yielded higher salinities and homogenization temperatures than fluid inclusions in quartz which implies there were at least two fluids of different origins involved in the mineralizing process at the Schlaining stibnite deposit. This is in line with the results of isotope and chemical analyses of fluid inclusions in quartz and stibnite presented here. The two fluids did not mix, which becomes obvious when plotting the isochores for fluid inclusions hosted in quartz and stibnite in a P–T diagram (Fig. 10). Assuming pressure conditions of less than 1 kbar during fluid entrapment (Belocky et al. 1991), the isochores for aqueous fluid inclusions in quartz and stibnite do not intersect and exclude mixing of the two fluids.
Hydrothermal calcite associated with stibnite mineralization rarely contains aqueous carbonic inclusions in addition to aqueous two-phase inclusions (Belocky et al. 1991). CO2 was detected in the vapor phase of all quartz-hosted aqueous two-phase inclusions analyzed by Raman spectroscopy. Traces of CH4 but no H2S are contained besides CO2 in a few inclusions (Fig. 5). The salinities and homogenization temperatures of calcite-hosted fluid inclusions are similar to those of two-phase fluid inclusions in quartz (Belocky et al. 1991), suggesting that quartz and calcite precipitated from the same fluid, hereinafter named Fluid I. The 87Sr/86Sr isotope ratio of gangue calcite is between 0.712 and 0.713 (Grum et al. 1992) and is within the range of 87Sr/86Sr ratios typically reported for hydrothermal carbonates from carbonate-hosted mineralization of the Eastern Alps (Frimmel 1988; Frimmel and Niedermayr 1991). Greenschist rocks of the Pennine units are excluded as the Sb source due to their lower 87Sr/86Sr isotope ratios compared to vein calcite, with the prerequisite that calcite and stibnite precipitated from a single fluid (Grum et al. 1992). The same holds true for a direct relationship between the origin of the ore-forming fluid and andesitic volcanism (Grum et al. 1992). Instead, these authors favor models for the origin of the ore fluid that invokes (i) mobilization of Sb from hypothesized deep-seated antimony mineralization by ascending metamorphic fluids or (ii) alteration of deep-seated crustal rock units by descending meteoric water and ore formation by fluid circulation and cooling into the Penninic calcareous schists. Grum et al. (1992) proposed a maximum age of 19–17 Ma for the stibnite mineralization and an epigenetic rather than a syn-sedimentary/early diagenetic origin (Nawaratne 1989). In contrast, Belocky et al. (1991) proposed a model that invokes localized high heat-flow triggered by Miocene andesitic magmatism and formation of epithermal stibnite mineralization at a shallow depth from low-salinity fluids at temperatures of at least 210 °C. A relationship between high heat flow, coalification of organic matter, and ore formation triggered by hidden magmatic intrusions in the Rechnitz Window is excluded by Dunkl et al. (1998). Instead, high heat flow is explained by tectonic denudation during the early Miocene (Dunkl et al. 1998).
There are several arguments to believe that the antimony mineralization of Schlaining is a typical epigenetic carbonate replacement deposit that was formed during the Miocene in response to fluid migration triggered by high heat flow induced by tectonic movements (Fig. 12). However, since a single fluid source for ore and gangue minerals in the Schlaining ore district can be excluded, previous geochemical studies that focussed on gangue minerals alone could have led to misleading conclusions about the origin of the ore fluid.
Fluid origin and ore deposition
The fluid inclusion salinity and homogenization temperatures from this study are consistent with those previously reported from quartz and calcite from the Schlaining Sb deposit (Belocky et al. 1991). The isotope data of the fluid that precipitated quartz (Fluid I) plot in the field of metamorphic water on the δ2H vs. δ18O diagram (Fig. 8). Considering oxygen isotope exchange reactions between fluid inclusions and quartz during cooling (Rye and O’Neil 1968), the measured δ18Owater values of 9 to 12‰ are too low and should be shifted to higher values (mean 17.3‰ at 270 °C, see previous discussion regarding re-equilibration) but still plot within the metamorphic water field (Fig. 8). Analyses from quartz in other alpine Sb mineralization have reconstructed δ18Owater values between 10 and 14‰ and δ2Hwater values between − 40 and − 65‰ (Schroll and Prochaska 1997) and also plot in the field for metamorphic water in Fig. 8.
However, low-salinity metamorphic fluids are often characterized by the presence of CO2 that is released by volatilization reactions such as dehydration or decarbonation (e.g., Yardley and Cleverley 2015, and references therein). Consequently, aqueous-carbonic or CO2-bearing fluid inclusions are commonly found in quartz and/or carbonates from metamorphic environments including, for example, many Au deposits. Aqueous carbonic or carbonic inclusions were not observed in gangue quartz, but trace amounts of CO2 and CH4 were detected in quartz-hosted aqueous two-phase inclusions (Fig. 5). Similarly, rare CO2-bearing fluid inclusions were reported from gangue calcite that are assumed to originate from the same fluid as quartz (Belocky et al. 1991).
Whereas the δ18Owater record of quartz should be considered with caution, fluid inclusion water in stibnite is unlikely to have been affected by oxygen isotope exchange processes, since this mineral is devoid of oxygen. The water isotope compositions of stibnite-hosted fluid inclusions (Fluid II) strongly suggest a different, non-metamorphic origin of this fluid (Fig. 8). The low δ2Hwater values ranging between − 66.1 and − 43.3‰ exclude a seawater origin for Fluid II (e.g., Holser 1979). The δ18Owater values of fluid inclusions in stibnite essentially follow a horizontal evolution trend for meteoric water that has shifted towards higher δ18OWater values due to water–rock interaction (e.g., Horita 2005). The contribution of secondary fluid inclusions in the WL sample does not show up clearly, since these secondary inclusions are likely to also be composed of meteoric water, which has a present-day isotope composition of around − 10‰ for δ18O and − 70‰ for δ2H in the area (Hager and Foelsche 2015). Interactions between deeply circulating heated meteoric water and Sb-bearing rocks such as black shales or greenschists are likely sources for the Sb and H2S enrichment in Fluid II.
Whether it was interaction between heated meteoric water and sedimentary or other rocks that led to a significant uptake of Sb in Fluid II, the sulfur isotope ratios (δ34S) from − 5.9 to − 8.4‰ (mean − 7.6‰) suggest a uniform source of sulfur (Pak et al. 1981). The negative δ34S values point to a reduced sulfur source (e.g., sediments) rather than a magmatic (e.g., ophiolites) source if the fluid had not experienced significant changes in pH and/or ƒO2 (Ohmoto and Lasaga 1982). At low ƒO2 and pH values and a temperature of 250 °C, the δ34S values of sulfides would not differ significantly from an initial δ34SƩS of about 0‰ if the source was magmatic. High ƒO2 values can be excluded as considerable amounts of barite would have precipitated (Ohmoto and Lasaga 1982) which is absent in the Schlaining district (Lehnert-Thiel 1967).
Stibnite solubility in hydrothermal fluids at about 300 °C (the temperature we have determined in this study) is extremely high regardless of the presence of H2S, pH, or fO2 but diminishes on cooling (Krupp 1988). Therefore, rapid cooling of Sb-bearing fluids is believed to be the most important means of promoting stibnite precipitation (e.g., Munoz et al. 1992; Wagner and Cook 2000; Hagemann and Lüders 2003). Several studies of stibnite-hosted fluid inclusions using near-infrared light have revealed that worldwide stibnite precipitated from low to moderately saline fluids at temperatures mostly below 200 °C (e.g., Lüders 1996; Bailly et al. 2000; Germann et al. 2003; Buchholz et al. 2007; Sun et al. 2014; Shimizu 2018) or from H2O-CO2-NaCl-bearing fluids at temperatures up to 250 °C (Hagemann and Lüders 2003; Krolop et al. 2018).
At temperatures above 300 °C, high concentrations of Sb will be transported in the fluid as hydroxothioantimonite complexes Sb2S2(OH)2(aq) (Krupp 1988) or hydroxide complexes Sb(OH)3(aq) (Zotov et al. 2003) rather than bisulfide complexes, e.g., Sb2S42−, HSb2S4−, H2Sb2S4(aq). Both hydroxybisulfide and hydroxide species are stable over a wide range of pH conditions (acidic and acidic to near-neutral, respectively) and form at low H2S activities in the fluid (Krupp 1988; Williams-Jones and Norman 1997; Hagemann and Lüders 2003). A low H2S activity is assumed based on the lack of other accompanying sulfide precipitation during the main Sb mineralization stage. The low salinities (5.7–7.1 wt.% NaCl equiv.) in primary fluid inclusions confirm that chloride complexes did not contribute to the transport of Sb in the hydrothermal fluid. Changes in the physico-chemical conditions are required to destabilize the metal transporting complexes leading to stibnite precipitation. Adiabatic cooling of hydrothermal Sb-bearing fluids below about 300 °C reduces the Sb solubility considerably and induces stibnite precipitation (Fig. 11). The stibnite-forming reaction involves the consumption of H2S from the fluid (Krupp 1988):
The microthermometric data from stibnite-hosted primary and pseudo-secondary fluid inclusions define a cooling trend, at relatively stable salinities (Fig. 6) and together with the mono-mineralic stibnite ore confirm the likelihood that cooling below 300 °C induced ore formation.
Under such temperature conditions, a maximum pressure of ~ 800 bar during stibnite formation can be derived from Fig. 10. Assuming pressure conditions close to lithostatic and a density of 2.6 g/cm3, the stibnite deposit at Schlaining therefore formed at a maximum depth of about 3 km. Belocky et al. (1991) suggested that the stibnite mineralization at Schlaining formed at shallow depth and estimated pressure conditions between 300 and 800 bar (dashed fields in Fig. 10) corresponding to depths between 1200 and 3000 m (Fig. 10). Dunkl et al (1998) calculated that the syn-rift burial depth of the hanging wall margin of the Rechnitz Window was 1100 to 1600 m. At such depths, stibnite deposition would have occurred at pressures between about 300 and 400 bar (lithostatic pressure conditions) and temperatures between about 260 and 280 °C (Fig. 10). Quartz would have been deposited at temperatures between about 220 and 240 °C (Fig. 10). There is compelling evidence that fluids from at least two different sources at temperatures greater than 250 °C were involved in ore and gangue mineral formation in the area of the Rechnitz Window. Fluid release and migration were probably related to high heat flow during the Early Miocene (Fig. 12). This was in response to the rapid uplift of the Mesozoic Penninic units with contemporaneous subduction along the Carpathian arc and opening of the Pannonian Basin (Ratschbacher et al. 1990; Dunkl and Demény 1997; Dunkl et al. 1998). However, there is a suggestion that the migration of fluids and ore deposition at Schlaining was triggered by Miocene andesitic magmatism (Belocky et al. 1991) or by high heat flow related to tectonic denudation during the early Miocene (Dunkl et al. 1998).
Although the sources of major ore components for stibnite mineralization are not definitely known, the fluid origin can be constrained based on the results of this study. The He isotope ratios indicate the presence of a mantle He component in the fluid inclusions which was probably derived from Miocene andesites. However, Fu et al. (2020) have shown that primary magmatic fluids are not enriched in Sb and thus do not contribute directly to the metal budget of economic stibnite deposits. δ2H and δ18O isotope ratios of stibnite-hosted fluid inclusions indicate that stibnite was very likely deposited from a meteoric fluid. Assuming that the ore-forming fluid was saturated with respect to H2S, the negative δ34S values of stibnite point to a supply of sulfur and Sb leached from black shales or metasediments such as greenschists rather than from Miocene andesites or surrounding ophiolites including altered MORB (Jochum and Verma 1996). It is also unclear whether the fluids originated from reservoirs located in the Eastern Alps or if the ore Fluid II was expelled from the Pannonian Basin and migrated along deep-reaching shear zones (Fig. 13). However, a selection/exclusion of possible fluid sources solely based on Sr isotope ratios in gangue calcite alone (Grum et al. 1992) is problematic as this study has shown that stibnite precipitated from a different fluid to calcite. Conclusions based on fluid inclusions in quartz which are clearly different to those in stibnite will also lead to errors. In the Schlaining mining district, quartz was precipitated from CO2-bearing metamorphic Fluid I, which most likely originated from distal Paleozoic greywackes or gneisses in the basement. Although fluids that precipitated quartz and stibnite had a different origin, they did so at the same time in the deposit without mixing with each other.
Conclusions
Comprehensive analyses of fluid inclusions hosted in quartz and stibnite document the involvement of at least two fluids from different sources that were responsible for the formation of (i) gangue minerals and (ii) stibnite at the Schlaining Sb deposit.
Quartz-(calcite)-forming Fluid I was of metamorphic origin and is characterized by a salinity similar to seawater and low CO2 concentration. The abundance of non-atmospheric He in fluid inclusions is considerably lower in quartz than in stibnite.
Stibnite-forming Fluid II originally was of meteoric origin that seeped down along permeable structures into a hot reaction zone where it became enriched in the mantle and crustal He, Sb, and H2S by interaction with sediments, probably black shales and/or metasedimentary rocks (e.g., phylites, greenschists).
Both fluids did not mix at the depositional site. Stibnite deposition occurred by cooling of Fluid II from temperatures of about 300–260 °C, at shallow depth, below 2000 m, i.e., under epithermal conditions. Fluid migration and ore deposition are likely related to high heat flow in response to Neogene extension and/or shallow Early Miocene andesitic magmatism.
Our study emphasizes that data obtained from geochemical analyses of gangue minerals cannot routinely be used to infer the origin and depositional conditions of the associated ore minerals. Thus, all conclusions concerning the origin and formation of the Schlaining stibnite deposit that are based on results, e.g., of fluid inclusion studies in gangue minerals or Sr isotope ratios in gangue calcite only have to be considered with caution.
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Acknowledgements
We are particularly indebted to R.T. Schmitt (Museum für Naturkunde Berlin), W. Ließmann (TU Clausthal), and F. Melcher (Montanuniversität Leoben) for providing the sample material from the Schlaining stibnite deposit. We are also grateful for the technical assistance of C. Preinfalk (München) and E. Schnabel (GFZ Potsdam). We would like to thank Mineralium Deposita chief editor B. Lehmann and W. Pohl for the critical review of the manuscript and useful comments.
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Sośnicka, M., de Graaf, S., Morteani, G. et al. The Schlaining quartz-stibnite deposit, Eastern Alps, Austria: constraints from conventional and infrared microthermometry and isotope and crush-leach analyses of fluid inclusions. Miner Deposita 57, 725–741 (2022). https://doi.org/10.1007/s00126-021-01076-x
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DOI: https://doi.org/10.1007/s00126-021-01076-x