Abstract
Hydrothermal fluid flow along fault zones in the Harz Mountains led to widespread formation of economic vein-type Pb–Zn ore and Ba–F deposits during the Mesozoic. We reconstruct the fluid flow system responsible for the formation of these deposits using isotope ratios (δ2H and δ18O) and anion and cation contents of fluid inclusions in ore and gangue minerals. Building forward on extensive studies in the 1980s and 1990s, our new geochemical data reveal that seawater evaporation brines, which most likely originated from Zechstein evaporites, descended deeply into Paleozoic rocks to leach metals at depth. In Jurassic times, these metal-rich brines episodically recharged along fault zones and mixed with shallow crustal H2S-bearing brines. Primarily in the Upper Harz Mountains, this mixing system led to the formation of economic Pb–Zn–Cu mineralization, which locally shows banded textures with alternations of sulfide minerals and quartz or carbonate (mostly calcite). In the Middle and Lower Harz Mountains, Zechstein-derived brines interacted with K- and F-bearing basement rocks and/or magmatic rocks to deposit fluorite mineralization upon ascent in the Upper Cretaceous. The proposed model of mineralizing fluids originating as (evaporated) seawater has been shown to hold for numerous basin-hosted base-metal sulfide and fluoride deposits elsewhere in Europe.
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Introduction
Hydrothermal vein-type deposits in the Harz Mountains (Harz Mts.) were mined from the Middle Ages until the end of the twentieth century and have been the subject of scientific research for over 100 years (Fig. 1). Initial ideas on the origin of vein-type mineralization in the Harz Mts. strongly diverged. Whereas Stahl (1929) proposed a Mesozoic age for vein-type mineralization in the Upper Harz Mts., mid-twentieth century research generally assumed that the expulsion of magmatic fluids from Late Carboniferous granitic intrusions caused widespread deposition of sulfide, fluorite, and barite-rich veins (e.g., Dahlgrün 1950; Jacobsen and Schneider 1950; Wilke 1952).
From the 1980s onwards, a large number of geochemical studies (including isotope ratios, minor and trace element distributions, fluid inclusion microthermometry, isotope geochronology, etc.) revealed compelling evidence that the economically most important Pb–Zn, fluorite, and barite vein-type mineralization in the Harz Mts. was deposited during the Mesozoic from highly saline NaCl–CaCl2-rich brines (Möller et al. 1984; Behr et al. 1987; Behr and Gerler 1987; Lüders and Möller 1992; Haack and Lauterjung 1993; Hagedorn and Lippolt 1993; Lévêque and Haack 1993a, b; Lüders et al. 1993a, b; Zheng and Hoefs 1993; Schneider et al. 2003a). These new insights, thus, argued against a genetic link to Late Carboniferous granitic plutons. Möller and Lüders (1993) summarized the results of interdisciplinary research on the Pb–Zn, fluorite, and barite deposits in the Harz Mts. and concluded that mixing of metal-rich saline brines with reduced sulfur-bearing fluids gave rise to the deposition of quartz–sulfide and carbonate–sulfide ores along WNW–ESE striking fracture zones. Subsequent mixing of metal-rich brines and sulfate-rich fluids led to the formation of economic barite mineralization in the Middle Harz Mts. Fluorite mineralization, which is completely absent in the Upper Harz Mts., marks the end of hydrothermal activity in the Middle and Lower Harz Mts. and is assumed to be related to the remobilization of fluorine from deep-seated reservoirs in Upper Cretaceous times.
Despite the achieved progress in characterizing the fluid flow system that underlies ore deposition in the Harz Mts., the precise origins of fluid salinity and mineral-forming constituents have remained a topic of debate. For example, whereas some studies suggest that ore-forming brines originated from Zechstein evaporites (Lüders and Möller 1992; Augustin 1993), other studies argue for major salinity uptake by basinal fluids through interaction with Paleozoic sediments or crystalline source rocks (Lévêque and Haack 1993a, b; Schneider et al. 2003b). Yet other studies suggest an important role of magmatic and metamorphic fluids (Möller et al. 1984; Behr et al. 1987). In this contribution, we use δ2H and δ18O data and anion and cation concentrations of fluid inclusion water trapped in hydrothermal vein minerals to trace the origin of the saline brines that were responsible for the deposition of Mesozoic Pb–Zn, barite, and fluorite mineralization and improve the existing fluid flow models.
For the acquisition of anion and cation concentrations, we performed crush-leach analysis on mineral bands from selected banded ores of the Upper Harz Mts. and present these data together with the so far unpublished crush-leach analysis data base of Kaden (2002). Microthermometric analysis was performed on fluid inclusions hosted in ore and gangue minerals from selected banded ores, and the data obtained are compared with previous data. For isotope analysis of fluid inclusion water, we applied a continuous-flow technique that consists of low-temperature crushing of samples and allows for on-line analysis of both δ2H and δ18O from a single water release (Vonhof et al. 2006). This technique bypasses typical analytical problems of thermal decrepitation techniques (e.g., Simon 2001). For example, the release of structural-bound water in OH-groups by decrepitation at high temperatures is known to cause significant deviations in fluid inclusion isotope ratios for fluorite (Baatartsogt et al. 2007b) and quartz (Grant et al. 2003). The low-temperature crushing technique already has a record of producing reliable isotope data when applied to low-temperature calcite veins (De Graaf et al. 2017, 2019; Bertotti et al. 2017).
Background
Geology of the Harz Mts.
The Harz Mts. in Northern Germany are part of the metallogenetic belt of the Variscan Orogen in Central Europe. The Harz Mts. consist of strongly foliated and faulted Ordovician to Carboniferous low-grade to nonmetamorphic sedimentary successions of mainly siliciclastic composition (e.g., Franke 1989; Lüders et al. 1993c; Schneider et al. 2003a). The thickness of the Lower Devonian to Lower Carboniferous sequence (shales, limestones, sandstones, and greywackes) significantly increases toward the northwest reaching up to approximately 6 km in the Upper Harz Mts. (Bormann et al. 1989). Based on stratigraphic and structural features, the Harz Mts. are subdivided from west to east into three units, namely, the Upper, Middle, and Lower Harz Mts. (Fig. 1).
Autochthonous sedimentation accompanied by submarine extrusion of basic magma led to the formation of world-class SEDEX deposits in the Paleozoic sequence of the Upper and Middle Harz Mts. (Middle Devonian Pb–Zn–Cu deposit of Rammelsberg and Fe deposits in the Elbingeröder complex, respectively). Syn-orogenic magmatism is present as the Bad Harzburger gabbro intrusion in the northeast of the Upper Harz Mts. The emplacement of post-orogenic granitic melts in the Late Carboniferous and melaphyres and porphyries in Permian times was closely controlled by the tectonic framework inherited from the Variscan Orogeny (e.g., Lüders et al. 1993c; Mohr 1993). The Harz Mts. were eroded during the Rotliegend before thick layers of Zechstein evaporites precipitated in shallow marine conditions. Sedimentation of Mesozoic sandstones, limestones, evaporites, and clays continued until uplift of the Harz Mts. block that began in the Cretaceous. The uplift lasted throughout the Tertiary and caused erosion of the Mesozoic cover and exposure of the Paleozoic rock sequences at the surface.
Vein mineralization in the Harz Mts.
The Paleozoic rocks of the Harz Mts. host a wide variety of vein-type mineralization that mostly occurs along WNW–ESE striking shear zones up to 15 km long. The shear zones originate from normal or oblique strike-slip faulting along reactivated Variscan fault systems during the Mesozoic (Franzke and Zerjadtke 1993; Stedingk and Stoppel 1993). On a regional scale, the shear zones are mainly restricted to several NNE–SSW-oriented lineaments of elevated tectonic activity. The end of the Variscan Orogeny marked the onset of minor vein mineralization in the Harz Mts. The initial phases of late Variscan vein mineralization are only recognized in the Lower Harz Mts. and are characterized by minor fluorite, quartz–wolframite, and quartz–stibnite assemblages (Franzke and Zerjadtke 1993). Late Variscan vein mineralization was of only marginal economic interest, compared to the three main Mesozoic mineralization events referred to as the sulfide, barite, and fluorite mineralization stages (e.g., Lüders and Möller 1992; Lüders et al. 1993c).
Pb–Zn (± Cu–Ag) sulfide-stage deposits mainly occur in the Upper Harz Mts. and were of great economic importance with a total crude ore production of about 37 million tons over a mining period of about 500 years (Stedingk 2012). The sulfide mineralization stage, which developed in up to 20-m-thick fault zones after an early pre-ore stage I (with minor quartz–hematite–carbonate–pyrite–chalcopyrite, bleaching and reddening of wall rocks), is subdivided into several substages (IIa–d and IIIa–b) that are dominated by different ore and gangue minerals and ore patterns (Stedingk and Stoppel 1993). Quartz–calcite–galena and later sphalerite–calcite banded ores are characteristic of the mineralization stage II. At the Bad Grund deposit, about 50% of the total mineralization precipitated during substages IIIa and b and mostly consists of galena, pyrite, quartz, and carbonates (Stedingk and Stoppel 1993). The sulfide mineralization stage dates back to the Lower Jurassic and is primarily recognized in the Upper Harz Mts. (Haack and Lauterjung 1993). At that time, the Harz Mts. were covered by up to approximately 2000 m of Zechstein evaporites and Mesozoic sediments (Franzke and Zerjadtke 1993). Sulfide-stage vein deposits mostly precipitated at temperatures between 120 and 170 °C as measured from fluid inclusion studies (Lüders et al. 1993a; this study) and often display a banded texture with quartz–sulfide or carbonate–sulfide alternations (Fig. 2). It is noteworthy that the metal content of the veins decreases with depth, whereas the calcite content increases (Stedingk 1993). For example, the Lautenthal ore body is composed of thick, almost barren calcite at a depth of 400 m below sea level (Stedingk 1993).
After the sulfide mineralization stage, continued uplift of the Harz Mts. in the Cretaceous allowed for an influx of meteoric surface water and the deposition of barite mineralization at shallow crustal levels (Stoppel et al. 1983). Fluid salinity, as well as precipitation temperatures of the shallow crustal barite deposits (< 100 °C), shows a sharp decrease with respect to the preceding sulfide mineralization stage (Lüders et al. 1993a). Due to an increased uplift of the northern part of the Harz Mts., barite stage mineralization is only preserved along the southern and western margins of the Harz Mts. (Lüders and Möller 1992).
Fluorite veins accompanied by subordinate amounts of quartz and calcite characterize the third and final main Mesozoic mineralization event (Fig. 3). The occurrence of fluorite veins is restricted to the Middle and Lower Harz Mts. Fluorite mineralization in the Middle Harz Mts. along structures south of the Brocken granite was only of minor economic importance. Considerable fluorite mineralization in the vicinity and south of the Ramberg granite in the Lower Harz Mts. was mined until 1990. After the main Mesozoic mineralization events, only remobilization of primarily carbonates occurred (Stoppel et al. 1983).
Methods
Fluid inclusion microthermometry
Microthermometric measurements of fluid inclusions hosted in sphalerite and quartz from banded ores were conducted using a Fluid Inc. USGS heating freezing system mounted on a BX 50 Olympus microscope. Fluid inclusions in calcite were studied using a Linkam THSM 600 system on a BX53M Olympus microscope. Both heating/freezing stages were calibrated with synthetic fluid inclusion standards supplied by Synflinc.
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, 63 samples of quartz, calcite, galena, sphalerite, fluorite, and siderite from banded ores and sulfide- or fluorite-stage mineralization (ESM Table 1) were crushed to a 1–2-mm grain size. Quartz and fluorite samples were cleaned by boiling in aqua regia, followed by boiling several times in 18.2 ΜΩ water. Samples of other mineral types were only boiled several times in 18.2 ΜΩ water. Subsequently, the cleaned samples were dried. 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 mesh prior to analysis. Ion chromatography was used for analysis of the anions Cl, Br, and SO4 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, Br = 1 ppb, and SO4 = 30 ppb with an average precision, as determined from series of replicate analyses, of better than 10% relative standard deviation.
Concentrations of SO4 from some fluid inclusions hosted by quartz, calcite, and fluorite are unrealistically high due to the presence of calcium sulfates in calcite and small micron-sized sulfide inclusions in the other minerals. Therefore, we cannot rely on the validity of SO4 analyses in general. Calcium was not measured in calcite and fluorite. In sphalerite, galena, and some quartz samples, the concentrations of Ca were unrealistically high due to the presence of micron-sized Ca-bearing solid inclusions in the host minerals. Instead, absolute calcium concentrations were calculated from the charge balance, which indicates a lack of cations. Calcium is assumed to account for the lack of cations, as fluid inclusion microthermometry strongly suggests that the brines in the Harz Mts. are dominated by NaCl–CaCl2–H2O (Lüders et al. 1993a).
Isotope analysis
In total, 50 vein samples were selected from multiple outcrops and mines throughout the Harz Mts. for isotope analysis (ESM Table 1; code HZ). The suite of samples comprises both banded ores from the Upper Harz Mts. and regular vein-type deposits. The minerals analyzed cover the three main Mesozoic mineralization stages and include calcite, quartz, fluorite, barite, and the metal sulfides sphalerite, galena, and chalcopyrite. Part of the samples used for isotope analyses is the same as used for crush-leach analysis (ESM Table 1).
Fluid inclusion isotope analysis, with the methodology developed by Vonhof et al. (2006), was used to obtain δ18Ow and δ2Hw values of bulk fluid inclusion waters. This technique allows for fluid inclusion isotope characterization of mineral samples of up to 2 g. The first step in the analytical procedure consists of crushing the sample at 110 °C in the Amsterdam device, which is a crusher unit connected to a continuous-flow pyrolysis furnace (ThermoFinnigan TC-EA). The submicroliter amount of water that is liberated due to the opening of inclusions is vaporized and transported to a TC-EA reactor tube, which separates the water vapor into H2 and CO gas as a result of reaction with glassy carbon at 1400 °C. A cryo-focusing technique is applied prior to entry into the reactor tube to generate a water pulse short enough to be analyzed. The H2 gas and CO gas are consecutively measured in a continuous-flow isotope-ratio mass spectrometer (ThermoFinnigan Delta XP). A rapid magnet peak jump between the entries of H2 gas and CO gas allows for analysis of both hydrogen and oxygen isotopes from a single water release. Isotope values of fluid inclusion water are reported as δ2Hw and δ18Ow ratios relative to VSMOW. Routinely measured water standards, following the analytical protocol, are typically reproducible (1σ) within 0.3‰ for δ18Ow and 2.0‰ for δ2Hw.
Crushed calcite samples were retrieved after fluid inclusion isotope analysis and then analyzed for carbon and oxygen isotopes on a Thermo Finnigan Delta+ mass spectrometer equipped with a GASBENCH II preparation device. Around 10 μg of sample material was placed in a He-filled 12-ml exetainer vial before sample digestion in concentrated anhydrous H3PO4 at a temperature of 45 °C. The generated CO2–He gas mixture was transported to the GASBENCH II in a He carrier flow. In the GASBENCH II, water was extracted from the gas through nafion tubing, and CO2 was analyzed in the mass spectrometer after extraction of residual gases in a GC column. Each sample was measured at least twice to determine the analytical precision. Isotope values for calcite are reported as δ13Cc and δ18Oc ratios relative to VPDB. The typical reproducibility (1σ) of routinely analyzed calcite standards is better than 0.10‰ for both δ13Cc and δ18Oc.
Results
Fluid inclusion characteristics
The petrography of fluid inclusions and their characteristics as determined from microthermometry in the different minerals from vein deposits in the Harz Mts. have been well-characterized (e.g., Adeyemi 1982; Behr et al. 1987; Behr and Gerler 1987; Lüders 1988; Lüders and Möller 1992; Augustin 1993; Lüders et al. 1993a; Lüders and Reutel 1998). Ore and gangue minerals from the Mesozoic vein-type deposits host abundant high-salinity aqueous two-phase fluid inclusions (Fig. 4). Three-phase (liquid + vapor + halite) inclusions are rare and, when present, are commonly hosted in fluorite from veins in the Lower Harz Mountains (Fig. 4f). They typically show irregular shapes and occur along secondary trails. Only barite mineralization is characterized by the presence of mostly all-liquid aqueous inclusions. The majority of homogenization temperatures fall between 100 and 160 °C (Lüders et al. 1993a); only a few primary fluid inclusions with homogenization temperatures above 200 °C have been reported (Lüders et al. 1993a; Augustin 1993). However, considering the Harz Mts. were covered by about 2 km of Zechstein evaporites and Mesozoic sediments, nearly lithostatic pressure conditions at the time of ore formation have to be taken into account (Franzke and Zerjadtke 1993). Under such pressure conditions of about 500 bars, a correction of about 20 °C, added to the measured homogenization temperatures, is needed to obtain the true trapping temperatures (Potter 1977).
In some instances, low-temperature microthermometry of high-salinity fluid inclusions in quartz from the sulfide stage and fluorite from the fluorite stage revealed phase transitions (i.e., eutectic temperatures and coupled melting of ice and hydrohalite) that are comparable to experimental data of Davis et al. (1990) and Spencer et al. (1990), indicating a brine composition of about 28–30 NaCl–CaCl2 equiv. wt% and a variable cation content of 3–15 NaCl equiv. wt% and 15–27 CaCl2 equiv. wt% (Lüders et al. 1993a). However, most of the reported first melting temperatures of fluid inclusions are below the eutectic of the CaCl2–NaCl–H2O system. Although this could have indicated the presence of significant concentrations of Li (Borisenko 1998; Zhang and Weisbrod 1988), we know from crush-leach analyses that Li is not present in the fluids in the concentrations required to lower the eutectic to the observed values. Hence, the low first melting temperatures are most likely due to observing a metastable eutectic in the CaCl2–NaCl–H2O system (Davis et al. 1990).
Chevron quartz, which commonly occurs in hydrothermal Pb–Zn vein mineralization of the Harz Mts., hosts primary and pseudosecondary fluid inclusions in and between growth zones (Fig. 4e). Fluid inclusions hosted in chevron quartz from Pb–Zn veins in the Harz Mts. generally show narrow ranges of ice melting temperatures for individual mineralization substages (Adeyemi 1982; Lüders et al. 1993a; Fig. 5). In veins from the eastern vicinity of the Brocken granite, on the other hand, ice melting and homogenization temperatures may vary considerably between distinct growth zones of single chevron quartz crystals. This is suggestive of, locally, the presence of a lower salinity fluid together with the high-salinity CaCl2–NaCl–H2O brines (Behr et al. 1987; Lüders 1988; Lüders et al. 1993a). Although trails with secondary fluid inclusions are also present in chevron quartz, their contribution to the total fluid inclusion water budget is negligible as their contents are volumetrically insignificant.
Fluorite-hosted fluid inclusions that bear halite daughter crystals show relatively low homogenization temperatures in the range of 100 to 120 °C, followed by melting of halite at temperatures between 150 and 180 °C (Augustin 1993).
Fluid inclusions in sulfide-stage minerals
Fluid inclusions in ore and gangue minerals from the sulfide stage of the Upper Harz Mts. have previously received little attention due to their less frequent abundance and small size. Most data were obtained from studies of fluid inclusions in quartz and calcite, and a compilation of the data is given by Lüders et al. (1993a). In this study, microthermometric measurements were conducted on sphalerite, calcite, and quartz from the sulfide substages IIb–d and IIIa of the main sulfide stage. The samples studied are from banded ore specimens from the Bad Grund deposit and the Burgstätte vein at Clausthal, in the Upper Harz Mts. (Fig. 1). Primary fluid inclusions in sphalerite from banded ores predominantly occur as isolated inclusions or are arranged along distinct growth bands (Fig. 4a–c). Primary aqueous two-phase inclusions in calcite from banded ores are typically small and their sizes are less than 10 μm (Fig. 4d). Calcite from banded ores is characterized by narrow twin lamellae that are not cross-cut by trails of secondary fluid inclusions. Quartz samples from banded ores and other Mesozoic vein mineralization of the Harz Mts. are characterized by distinct zoning. Primary fluid inclusions associated with growth zones are abundant (Fig. 4e).
The studied fluid inclusions in all minerals contain a high-salinity fluid which decreases in salinity at the Bad Grund deposit in substage IId and the subsequent stage IIIa (Fig. 5). Homogenization temperatures increase from substage IIb through to IId, but then decrease in quartz from substage IIIa (Fig. 5). Banded ore sphalerite-hosted fluid inclusions have a similar range of homogenization temperatures and slightly higher salinities than the fluid inclusions in calcite from adjacent bands.
Banded ores from the Burgstätte vein at Clausthal, which is located some 6 km east of the Bad Grund, were deposited from fluids of similar salinity, but at higher temperatures than the banded ores from the Bad Grund deposit. Fluid inclusions in quartz from the Burgstätte vein at Clausthal have the same salinity and Th range as fluid inclusions in several other veins from the Upper Harz Mts. (including Todberg, Schulenberg, Zellerfeld, and Lautenthal; ESM Table 2), which are included in field IIc/IId/IIIa in Fig. 5 for comparison. The highest homogenization temperatures were measured in primary fluid inclusions hosted in sphalerite from the Burgstätte vein at Clausthal (ESM Table 2).
Crush-leach analyses
In order to elucidate the source(s) of salinity, anion and cation concentrations of fluid inclusions hosted in ore and gangue minerals from various parts of the Harz Mts. and in different mineralization stages were analyzed (ESM Table 3A-3B). The data are plotted in a Na–Cl–Br diagram, as proposed by Walter et al. (1990). This diagram can be used to discriminate between different solute sources and, furthermore, has the advantage that molar ratios are unaffected by dilution with meteoric water (Kesler et al. 1995).
In Na/Br vs Cl/Br diagrams of the different mineralization stages, the data plot close to the seawater evaporation trend (Fig. 6), which indicates that the ore-forming fluids were mainly marine in origin. The position of the data slightly to the left of the seawater evaporation line is indicative of loss of Na through water–rock exchange reactions. For example, Na may be lost from fluids through exchange with Ca in plagioclase (Davisson and Criss 1996) or through albitization of K-feldspar (Banks et al. 2002; Möller et al. 2017). Banded ore sulfides from the Upper Harz Mts., galena from the St. Andreasberg Pb–Ag deposit in the Middle Harz Mts., and fluorite mineralization show K enrichment in Na/K vs Cl/Br diagrams (Fig. 7a–c), which indicate that Na–K exchange between fluids and minerals was an important process.
Fluid inclusions in banded ores from the Upper Harz Mts. have Cl/Br molar ratios that cover a large range along the seawater evaporation line (Fig. 6a). Fluid inclusions in galena and sphalerite from banded ores have Cl/Br molar ratios similar or slightly lower to seawater, whereas quartz and calcite samples from adjacent bands have considerably lower fluid inclusion Cl/Br molar ratios. It is conspicuous that fluid inclusions hosted in quartz from quartz–sulfide banded ores yield more variable but always higher Cl/Br and Na/Br molar ratios than fluid inclusions in calcite from carbonate–sulfide ores. Also in Na/K vs Cl/Br diagrams (Fig. 7a), sulfides and gangue minerals from the banded ores plot in distinctive areas, possibly due to the interaction of fluids with different lithologies either in the fluid reservoir or along the flow path to the sites of ore deposition. There are no clear patterns in Cl/Br, Na/Br, and Na/K molar ratios of fluid inclusions in sulfide- and fluorite-stage mineralization in the Middle and Lower Harz Mts. (Figs. 6b, c and 7b, c). In a Na–Cl–Br diagram, the crush-leach data of fluorite-stage mineralization from the Lower Harz Mts. plot further away from the seawater end-member along the seawater evaporation trend compared to banded ores (Fig. 6c).
Li was analyzed in the fluids to confirm if the low eutectic temperatures were due to the presence of high Li concentrations. The analyses, however, show that Li concentrations were too low for this to account for the first melting temperatures.
Fluid inclusion isotope data
Water yields (0.1 to 0.8 μl) were sufficient to obtain reliable data for 46 samples (ESM Table 4). A complete overview of fluid inclusion isotope data is presented in Fig. 8. Fluorite has the highest isotope values ranging from 2.5 to 6.5‰ for δ18Ow and − 31 to 5‰ for δ2Hw with a positive correlation between the two variables. A similar positive correlation is present in vein-type calcite and quartz deposits in the Middle and Lower Harz, albeit shifted toward lower isotope values (− 7.8 to − 0.4‰ for δ18Ow and − 54 to − 15‰ for δ2Hw). Barite stands out with respect to the other analyzed minerals for its relatively depleted values, which are as low as − 8.8‰ for δ18Ow and − 72‰ for δ2Hw.
Fluid inclusion isotope signatures of metal sulfides from the Bad Grund Pb–Zn banded ores in the Upper Harz range from 0.4 to 2.9‰ for δ18Ow and from − 24 to − 7‰ for δ2Hw (Fig. 8). These values are quite similar to fluorite from occurrences in the Middle Harz Mts. and fluorite deposits in the Lower Harz Mts. Fluid inclusion water in calcite and quartz from the banded ores plot in isotopically distinct fields and toward lower δ18Ow and δ2Hw values compared to the sulfide minerals.
Carbon and oxygen isotope ratios of calcite
Carbon and oxygen isotope ratios of calcite from banded ores and other vein-type occurrences throughout the Harz Mts. are positively correlated and range from − 17.1 to − 10.8‰ for δ18Oc and − 10.6 to − 6.8‰ for δ13Cc (Fig. 9; ESM Table 4). These data are similar to extensive isotope analyses of calcite from the Harz Mts. by Zheng and Hoefs (1993), who suggested that water–rock interactions or temperature-dependent fractionation effects may underlie the clear co-variation between carbon and oxygen isotopes. The systematic isotope depletion of fluorite-stage calcite with respect to the older sulfide-stage calcite could be related to a change in water–rock interaction intensities, fluid temperatures, and/or sources for dissolved inorganic carbon (DIC). The carbon and oxygen isotope data of calcite samples do not provide signs of recrystallization, since recrystallized calcite from the Harz Mts. typically plots in a distinct field toward higher δ18Oc values and lower δ13Cc values (Lüders and Möller 1992; Zheng and Hoefs 1993).
Discussion
Banded ore deposition during the sulfide stage
Fluid mixing
The Mesozoic sulfide mineralization stage was of major economic importance and typically manifests itself as banded quartz–sulfide and calcite–sulfide ores or massive ore veins in the Upper Harz Mts. The formation of banded ores in the Upper Harz Mts. is commonly explained by mixing of ascending metal-rich brines with H2S-bearing fluids (e.g., Möller et al. 1979, 1984; Lüders and Möller 1992). Calcite that precipitated during the sulfide stage contains considerable amounts of metals such as Pb, Zn, Mn, Fe, Sr, and REE (Möller et al. 1984, 1991; Lüders 1988; Luck and Lüders 1989) and is, for that reason, believed to be associated with a metal-rich brine that ascended from a deep-seated source. Calcite contents of the veins in the Upper Harz Mts. typically increase with depth, whereas sulfide mineralization decreases (Stedingk 1993), which may be indicative of transport of metals into a shallower, H2S-bearing environment. Hence, the deposition of sulfides is assumed to result from the mixing of the ascending metal-rich brine with shallower crustal H2S-bearing fluids derived from Paleozoic shales (Nielsen 1968; Lüders and Möller 1992). A tectonic pumping mechanism could be capable of draining different reservoirs alternately causing cyclic changes in the fluid composition (Sibson et al. 1975). Fluid mixing is often cited as a key process for depositing ore bodies in hydrothermal systems (Wilkinson 2001; Boiron et al. 2010; Bons et al. 2014), and this model is compatible with the results of this study.
Differences in Cl/Br, Na/Br, and Na/K molar ratios between gangue and ore minerals (Figs. 6a and 7a) indicate that fluids from at least two different reservoirs were involved in the formation of banded ores. Both fluids are characterized by high salinity as indicated by fluid inclusion microthermometry of inclusions in ore and gangue minerals (Fig. 5). Variations in δ2Hw in banded ore minerals cover a range of 40‰. At the temperatures recorded from the fluid inclusions for the mineralizing events, hydrogen isotope values of fluid inclusions are generally assumed to be unaffected by diagenetic alteration (Horita and Matsuo 1986; Ohba and Matsuo 1988; Mavrogenes and Bodnar 1994; Simon 2001; Baatartsogt et al. 2007a; Bakker 2009). The large isotope range observed in δ2Hw is, thus, also indicative of fluids originating from different reservoirs, considering that δ2Hw modifications of circulating fluids through WRI processes are generally thought to be limited due to the sheer amount of water with respect to hydrogen-bearing reactants (e.g., O’Neil and Kharaka 1976; Yeh and Epstein 1978).
Deep-seated brines
Lead isotope ratios showed that lead in galena from Mesozoic sulfide-stage deposits was derived from a homogeneous crustal source (Lévêque and Haack 1993a). Uniform Sr isotope compositions of calcite (0.713–0.714) from the most important Pb–Zn deposits in the Upper Harz Mts. point to a homogeneous source for Sr as well (Lévêque and Haack 1993b). Assuming that Pb and Sr are derived from the same reservoir, alteration of granites and/or basement rocks can be excluded as possible sources of Sr and Pb in banded ores. Instead, Ordovician to Lower Carboniferous sedimentary sequences are believed to be the most probable source for the metal-rich brine (Friese and Haack 1993; Lévêque and Haack 1993a, b). Schneider et al. (2003b), studying Sr isotope ratios in siderites from the Lower Harz Mts., also concluded that Paleozoic sequences are the most likely source for Sr.
Halite dissolution can be excluded as source of salinity of fluids in the Harz Mts. as it typically produces brines with Cl/Br molar ratios of 5000 to 20,000 (Fontes and Matray 1993), which are significantly higher than those recorded for the Harz system (about 200 to 650). The principal source of salinity for the deep-seated brine is rather related to seawater evaporation (Fig. 6a). The δ2Hw of banded ore calcite and quartz (− 47 to − 17‰) is depleted with respect to seawater. Although the precise effects of WRI on the isotope composition of the brine are unconstrained, low δ2Hw values fit well with dense seawater evaporation brines, which are typically characterized by considerable depletions in 2H (Holser 1979; Knauth and Beeunas 1986).
The origin of the supposed evaporation brines seems to be enigmatic since evaporites do not occur in the Paleozoic sedimentary succession. An intriguing possibility, though, is that the seawater evaporation brines originated from the Zechstein evaporites that covered the Harz Mts. during the Mesozoic. Behr and Gerler (1987) also suggested a close relation between highly saline Permo-Triassic basinal brines and the formation of Post-Variscan mineralization in other ore districts in Germany. The increased density of Zechstein evaporite brines would have aided their descent into deep-seated Paleozoic sediments and their high chloride concentration would have made them ideal solvents for leaching metals. The driving force behind the descent of fluids may be fracture opening or the consumption at depth of water through hydration reactions with minerals (Stober and Bucher 2004). The deeply infiltrated brines ascended along faults during periodic pulses of tectonic activity to cause the deposition of banded ores through mixing with shallow crustal H2S-bearing brines.
Cl/Br molar ratios of fluid inclusions hosted in calcite are lower compared to quartz (Fig. 6a), which provides an indication that the brines that were active during the calcite–sulfide stage IIc had experienced greater seawater evaporation than the brines responsible for quartz precipitation. Progressively deeper reservoirs of denser fluids may have been tapped in response to tectonic activity and rupture propagation. Different reservoirs for quartz and calcite-forming brines are also supported by different δ2Hw values of fluid inclusion water in quartz and calcite (Fig. 10).
The original δ18O ratio of the deep-seated brine is difficult to constrain since it is associated with the oxygen-bearing minerals calcite and quartz. The drop in temperature that these minerals have experienced since their deposition has likely resulted in the decreasing of δ18Ow ratios due to in situ oxygen isotope re-equilibration between fluid inclusion water and the host mineral (Schwarcz et al. 1976; Matsuhisa et al. 1978; Ohba et al. 1995; Taylor 1997). This becomes evident when calculating temperatures from δ18Ow–δ18Omineral pairs. As for banded ore calcite, the calculated temperatures range from 58 to 79 °C using the equation of O’Neil et al. (1969). Banded ore quartz has a temperature range of 66 to 109 °C, when using the equation of Clayton et al. (1972) and δ18Oqtz values ranging from 18.6 to 21.8‰ vs VSMOW as reported for banded ore quartz in Voigt (1984) and Zheng (1991). These calculated temperatures are considerably lower than the (pressure-corrected) temperatures of hydrothermal fluids during sulfide-stage mineralization in the Upper Harz Mts. of up to 175 °C (Lüders et al. 1993a; this study). This suggests that the δ18Ow data from the banded ore calcite and quartz probably do not represent the original values as a result of water–mineral oxygen isotope re-equilibration. As an alternative, original δ18O values of the brines may be calculated from the δ18Oc data under the assumption of isotope equilibrium during mineral precipitation (Fig. 10). Whereas the δ18Ow record of calcite and quartz should be approached with caution, fluid inclusion water in fluorite (CaF2), sphalerite (ZnS), chalcopyrite (CuFeS2), and galena (PbS) is unlikely affected by oxygen isotope exchange processes, since these minerals are devoid of oxygen.
Shallow crustal fluid (H2S source)
Mixing of reduced sulfur-bearing fluids with the ascending brines induced the precipitation of sulfide minerals. Detailed studies of fluid inclusions hosted in individual quartz, calcite, and sphalerite bands as well as results of previous studies (Adeyemi 1982; Lüders et al. 1993a) have shown that ore and gangue minerals (incl. banded ores) were deposited from brines of similar salinity (Fig. 5). Cl/Br and Na/Br ratios suggest that the reduced sulfur-bearing fluid had experienced minor evaporation (Fig. 6a). The upper limit of fluid inclusion isotopes recorded in metal sulfides (− 5‰ for δ2Hw and 2‰ for δ18Ow) would correspond to the reduced sulfur-bearing fluid end-member and also points to a marine fluid that experienced a minor 18O enrichment due to subaerial evaporation or high-temperature WRI.
Paleozoic shale-rich units containing organic matter situated below the impermeable Zechstein evaporites are assumed to provide the main source of H2S necessary for sulfide mineral deposition in the Harz Mts. (Nielsen 1968; Lüders and Ebneth 1993). Na/K vs Cl/Br diagrams of banded ore galena and sphalerite samples show the brines had experienced a significant degree of K enrichment (Fig. 7a), which is in line with a model that involves interaction with shales (e.g., exchange reactions with or dissolution of K-bearing clay minerals). Whereas the Permian and Mesozoic rock cover has been eroded in the present-day Harz Mts., it is preserved in large parts of the North German Basin. Interestingly, formation waters from a Carboniferous reservoir in the North German Basin (Lüders et al. 2010) display isotope values (− 15 to 0‰ δ2Hw and − 3 to 4‰ δ18Ow), which are similar to those inferred for the shallow crustal fluid involved in banded-ore deposition, supporting a provenance from the Paleozoic units. Furthermore, it is noteworthy that CaCl2–NaCl–H2O Rotliegend brines, which reach up to 330 g/l of total dissolved solids (TDS), show similar Cl/Br and Na/Br ratios as the fluid inclusions in sulfide minerals (Lüders et al. 2010).
Fluid systems involving highly saline deep-seated brines that ascend to mix with shallow crustal fluids are often seen to be associated with the deposition of Pb–Zn ores (Boiron et al. 2010). Mixing of fluids from different crustal levels is hydromechanically feasible only when fluids mix during their ascent to shallower crustal levels (i.e., no simultaneous upwelling and downwelling of fluids) as set forth in the model of Bons et al. (2014). In this model, the amount of shallow crustal fluids may vary depending on the upwelling rate of deep-seated fluid batches; it can, thus, be reconciled with the observed vein banding. For many ore deposits, the driving force for the expulsion of deep-seated ore-forming fluids is related to periods of crustal extension. For example, the opening of the North Atlantic during the Jurassic to Early Cretaceous initiated extensional tectonic regimes that facilitated the deposition of ores throughout Europe (Muchez et al. 2005; Boiron et al. 2010) and basement-hosted Ag ores in the Anti-Atlas Mountains of Morocco (Essarraj et al. 2005). On a western European scale, continental rifting of the Rhine Graben instigated ore deposition during the Tertiary (Staude et al. 2009).
Barite mineralization stage
Barite veins were deposited at shallow crustal levels during the Cretaceous. The few studied barite samples display significantly lower δ2Hw values compared to the other analyzed minerals (Fig. 8). The position of barite samples on the GMWL could point to an influx of meteoric water (about − 75‰ for δ2Hw and − 10.5‰ for δ18Ow) into the system that may possibly have leached sulfate from the Zechstein evaporites to facilitate barite mineralization. The supply of SO42−-bearing meteoric waters during the barite mineralization stage was previously inferred from a general drop in fluid inclusion salinities (Lüders et al. 1993a).
Although fluid inclusion isotope data are consistent with traditional ideas on fluid flow during the barite stage, we are cautious with this interpretation since fluid inclusions in barite are relatively prone to remobilization and leakage (Ulrich and Bodnar 1988). Secondary monophase aqueous fluid inclusions predominate in barite, and although this could result from low entrapment temperatures, it could also be related to recrystallization or late infiltration of meteoric fluids at near-surface conditions. The isotopic resemblance of fluid inclusions in barite to present-day rainwater in the region (Stumpp et al. 2014) would support this latter hypothesis. Furthermore, the extent of post-depositional oxygen isotope re-equilibration of fluid inclusion water in barite cannot be assessed, since we do not dispose of oxygen isotope data of the mineral phase. Altogether, the exact reason for the recorded meteoric isotope character of fluid inclusion water in barite cannot be definitively constrained.
Fluorite mineralization stage
Fluorite-(calcite ± quartz) mineralization represents the last stage of Mesozoic vein-type deposition in the Harz Mts. and is mostly encountered in the vicinity of Upper Carboniferous granites and Permian volcanic rocks in the Middle and Lower Harz Mts. (Fig. 1). The origin of fluorine is assumed to be metavolcanic Lower Permian rocks (Schneider et al. 2003a) and/or dispersed fluorite enrichments in the crystalline basement (Lüders and Möller 1992). Whereas geochemical data of banded sulfide ores from the Upper Harz Mts. point to a mixing system with fluids derived from different Paleozoic reservoirs, the origin of fluorite-forming fluids has remained largely unresolved.
Fluid inclusions in fluorite samples show an isotope range for fluorite-forming fluids from 2.5 to 6.5‰ for δ18Ow and − 31 to 5‰ for δ2Hw. This wide isotope range could indicate interaction of brines with different rocks and/or that different fluid reservoirs were being accessed during the fluorite stage. Calculation of δ18O values of fluids associated with calcite precipitation during the period of fluorite mineralization—using the equation of O’Neil et al. (1969), with the measured δ18Oc values and assuming a precipitation temperature of 175 °C (Augustin 1993; Lüders et al. 1993a)—brings the fluid inclusion isotope range of calcite coincident with the range of the fluorite samples (Fig. 11). This suggests that fluorite and calcite precipitated from fluids derived from similar sources, which is also supported by overlapping Na/K molar ratios for these two mineral types in the Lower Harz Mts. (Fig. 7c). Radiogenic Sr isotope ratios in fluorite (Schneider et al. 2003b) and K enrichments in fluorite-hosted fluid inclusions would be compatible with a model that invokes refluxing Zechstein brines that interacted with deep-seated crystalline rocks and re-ascended along deeply penetrating compressional structures that were activated during Late Cretaceous tectonics (Franzke and Zerjadtke 1993). The Cl/Br molar ratios of vein-forming fluids during the fluorite stage (Fig. 6c) are significantly lower compared to the sulfide-stage banded ores and even suggest seawater evaporation past the end of halite saturation (Fontes and Matray 1993). This is in line with the observation of halite daughter crystal-bearing fluid inclusions hosted in some fluorite samples (Fig. 4f). The progressive tapping of more highly evaporated fluids through time would correspond with the expected stratification in fluid reservoirs based on density, with the densest fluids occupying the deepest crustal levels (Bons et al. 2014).
In the previous discussion, we provide a model in which the most important Pb–Zn and fluorite vein-type deposits in the Harz precipitated from deep-seated seawater-evaporated brines that mixed with variable amounts of shallow crustal fluids. The model of mineralizing fluids originating as seawater and/or evaporated seawater has been shown to hold for numerous other basin-hosted Pb–Zn ore and fluorite deposits (e.g., Behr and Gerler 1987; Gleeson et al. 2001; Heijlen et al. 2003; Grandia et al. 2003; Muchez et al. 2005; Stoffell et al. 2008; Leach et al. 2010) and in genetic models for Proterozoic U deposits (Derome et al. 2007; Boiron et al. 2010; Richard et al. 2011, 2013). Ore-forming seawater evaporation brines are systematically characterized by depletions in 2H similar in magnitude to those we observe (Baatartsogt et al. 2007a; Wilkinson 2010; Richard et al. 2013) and low Cl/Br ratios (Bucher and Stober 2010; Fusswinkel et al. 2013).
Conclusions
Isotopic (δ2Hw and δ18Ow) and salinity data of bulk fluid inclusions in ore and gangue minerals provide new constraints on the flow patterns and origins of ore-forming fluids in the Harz Mts. Considerable variations in fluid inclusion isotope ratios and salinities suggest that various fluid reservoirs were involved in the deposition of a wide variety of vein-type mineralization in the Harz Mts. Zechstein brines are recognized to be of major importance throughout the main mineralization stages during the Mesozoic. These dense, evaporated marine waters descended along fault structures to leach metals and other ore-forming constituents from deep-seated Paleozoic sediments (Upper Harz Mts.) and crystalline rocks (Lower Harz Mts.). Episodic events of tectonic activity forced the metal-rich brines upwards to enable ore deposition at shallower crustal levels.
During the Jurassic, the deep-seated brines recharged along shear zones and experienced mixing with H2S-bearing brines from shallower Paleozoic shale units, which resulted in the deposition of banded quartz–sulfide and calcite–sulfide ores in the Upper Harz Mts. Continued fracture propagation to greater depths allowed the leaching of fluorine-bearing basement rocks and the recharge of highly saline brines that deposited fluorite mineralization in the Middle and Lower Harz Mts. during the Cretaceous.
Fluid inclusion isotope data from barite deposits have a meteoric signature. This could point either to infiltration of meteoric fluids into the system during the barite mineralization stage, or to later alteration of fluid inclusion isotope ratios due to exposure to surface waters.
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Acknowledgments
Open access funding provided by Max Planck Society. We thank the Museum für Naturkunde Berlin and the Technical University Berlin for providing samples from their mineral collections. Suzan Verdegaal is thanked for technical support in the stable isotope laboratory at the VU University Amsterdam. Three anonymous reviewers are acknowledged for their critical reviews and valuable suggestions for improvement. We are indebted to Mineralium Deposita chief editor B. Lehmann for fair handling of this manuscript.
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ESM 1
Sample origin and applied analysis (δ18Ow, δ2Hw refer to fluid inclusion water; δ18Oc, δ13Cc refer to calcite) (DOCX 20 kb)
ESM 3
Concentrations of anions and cations from fluid inclusions as analyzed in the leach solution (data in ppb) and molar ratios. Samples marked with * are from this study. Other samples are from unpublished data of Kaden (2002). (DOCX 23 kb)
ESM 4
Reconstructed fluid composition of leachates in ppm (middle values) from Kaden (2002). Values for Ca are calculated from the charge balance. (DOCX 16 kb)
ESM 5
Isotope data of fluid inclusions (δ18Ow and δ2Hw in ‰ vs. VSMOW) in hydrothermal vein minerals and δ18Oc and δ13Cc isotope ratios (in ‰ vs. VPDB) of calcite samples (DOCX 17 kb)
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de Graaf, S., Lüders, V., Banks, D.A. et al. Fluid evolution and ore deposition in the Harz Mountains revisited: isotope and crush-leach analyses of fluid inclusions. Miner Deposita 55, 47–62 (2020). https://doi.org/10.1007/s00126-019-00880-w
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DOI: https://doi.org/10.1007/s00126-019-00880-w