Abstract
The Qianhe gold deposit in the Xiong’ershan area is located along the southern margin of the Archean-Paleoproterozoic North China Craton. The deposit consists of six orebodies that are hosted in Paleoproterozoic andesites to basaltic andesites and structurally controlled by roughly EW-trending faults. Individual orebodies comprise auriferous quartz veins and disseminated Au-bearing pyrite within hydrothermally altered rocks on both sides of, or close to, the veins. Ore-related hydrothermal alteration has produced various mixtures of K-feldspar, quartz, sericite, chlorite, epidote, carbonate, and sulfides. Pyrite is the most important ore mineral, associated with minor amounts of galena, sphalerite, and chalcopyrite. Other trace minerals include molybdenite, arsenopyrite, scheelite, rutile, xenotime, and parisite. Gold occurs mostly as native gold and electrum enclosed in pyrite or along microfractures of sulfides and quartz. Microthermometric measurements of primary inclusions in auriferous quartz suggest that gold and associated minerals were precipitated in the range of 160–305 °C from aqueous or carbonic-aqueous fluids with salinities of 6–22 wt% NaCl equiv. Samples of molybdenite coexisting with Au-bearing pyrite have Re–Os model ages of 134–135 Ma, whereas ore-related hydrothermal sericite separates yield 40Ar/39Ar plateau ages between 127 and 124 Ma. The Re–Os and 40Ar/39Ar ages are remarkably consistent with zircon U–Pb ages (134.5 ± 1.5 and 127.2 ± 1.4 Ma; 1σ) of the biotite monzogranite from the Heyu-intrusive complex and granitic dikes in and close to the Qianhe gold mine, indicating a close temporal and thus possibly genetic relationship between gold mineralization and granitic magmatism in the area. Fluid inclusion waters extracted from auriferous quartz have δD values of −80 to −72 ‰, whereas the calculated δ 18OH2O values range from 3.1 to 3.8 ‰. The hydrogen and oxygen isotopes from this study and previous work indicate that ore fluids were likely derived from degassing of magmas, with addition of minor amounts of meteoric water. Gold mineralization at Qianhe is temporarily coincident with pervasive bimodal magmatism, widespread fault-basin formation, and well development of metamorphic core complexes in the whole eastern North China Craton that have been interpreted as reflecting reactivation of the craton in the late Mesozoic after prolonged stabilization since its formation in the late Paleoproterozoic. It is therefore concluded that the Qianhe gold deposit formed as a result of this craton reactivation event.
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Introduction
Numerous gold deposits in the Xiong’ershan area, southern margin of the North China Craton (NCC), are hosted in Neoarchean high-grade metamorphic rocks or late Paleoproterozoic volcanic rocks (Mao et al. 2002; Chen et al. 2004). Many deposits have been extensively described in the last two decades (Fan et al. 1993, 1998; Mao et al. 2002; Lu et al. 2004a; Yang et al. 2003; Han et al. 2007; Chen et al. 2008a, 2009), but their origins remain debated or not well understood. Previous radiometric dating, mostly by K–Ar and Rb–Sr methods, bracketed the gold mineralization at between 595 and 87 Ma (Li and Qu 1993; Qiang et al. 1993; Ren et al. 1996, 2001; Lu et al. 2004b). The large scatter of those “ages” has complicated the understanding of the timing, genesis, and geodynamic setting of gold mineralization in the region. Lu et al. (1999, 2003) and Chen et al. (2008a; 2009) proposed that gold deposits in the Xiong’ershan area formed in the late Triassic to early Jurassic, associated with the evolution of the Triassic Qinling Orogen. In contrast, Mao et al. (2003, 2008a) and Yang et al. (2003) favored that they were results of late Jurassic to early Cretaceous extension or lithospheric thinning of the North China Craton. Precise isotopic dating is crucial to better understand the genesis and tectonic setting of the region-wide gold metallogenesis.
Being one of the largest gold deposits in the Xiong’ershan area, the Qianhe gold deposit (Fig. 1) has been a major focus of previous studies (Li et al. 1999; Pei et al. 2006; Cao 2007; Mao 2008; Wang et al. 2008a), but its formation age, source of ore fluids, and genesis are still poorly understood. Previous Rb–Sr dating of hydrothermal sericite and fluid inclusion waters extracted from Au-bearing quartz veins yielded inconsistent isochron ages of 99.3 ± 6.3 Ma (Qiang et al. 1993) and 155.2 ± 6.6 Ma (Ren et al. 1996), respectively. The large discrepancy in these ages makes it impossible to precisely time gold precipitation and reasonably constrain the ore genesis. In this paper, we present high-precision Re–Os, 40Ar/39Ar, and U–Pb ages in order to place tight constraints on the timing of gold mineralization and to examine the possible relationship between granitoid magmatism and ore formation. We further use fluid inclusion and stable isotope data to characterize and fingerprint the source of the ore fluids. Lastly, the geodynamic setting under which the Qianhe gold deposit was produced is discussed by integrating existing geological and geochronological data from other deposits in the Xiong’ershan area and other parts of the eastern North China craton.
Geological background
The Xiong’ershan area lies in the southern margin of the NCC (insert of Fig. 1). It is bounded by the Machaoying Fault to the south and the Luoning Fault to the northwest (Fig. 1). The area is lithologically dominated by amphibolite-facies metamorphic rocks of the late Archean to early Paloeproterozoic Taihua Group, which are unconformably overlain by intermediate to silicic volcanic rocks of the Paleoproterozoic Xiong’er Group (Chen et al. 2009; Mao et al. 2010; Fig. 1). The Taihua Group consists chiefly of sillimanite–garnet quartz gneiss, graphite gneiss, TTG (tonalite–trondhjemite-granite) gneiss, marble and amphibolite (Xu et al. 2009). The amphibolite and TTG gneiss have whole-rock Sm–Nd and zircon U–Pb age of 2.5–2.3 Ga (Kröner et al. 1988; Xue et al. 1995; Xu et al. 2009). The Xiong’er Group, up to 7,000 m in thickness and covering an area of >6000 km2, is widely distributed in the southern NCC (Peng et al. 2008; Zhao et al. 2009). Rocks of the Xiong’er Group consist of basaltic andesite and andesite with minor dacite and rhyolite. These rocks have SHRIMP and LA-ICP-MS zircon U–Pb ages of 1.80–1.75 Ga (Zhao et al. 2004; Peng et al. 2008; He et al. 2009). Mesozoic and Cenozoic redbeds are locally present in the area (Fig. 1).
Several major granitoid intrusions, mainly the Huashan, Wuzhangshan, and Heyu plutons, intrude the Archean and Paleoproterozoic rocks (Fig. 1). The Huashan pluton consists of monzogranite, granodiorite, and granite, with the monzogranite having a SHRIMP zircon U–Pb age of 132.0 ± 1.6 Ma (Mao et al. 2010). The Wuzhangshan pluton consists of hornblende granite, syenogranite, and granosyenite, and has a SHRIMP zircon U–Pb age of 156.8 ± 1.2 Ma (Mao et al. 2010). The Heyu pluton, with an outcrop of 784 km2, intrudes andesite and dacite of the Xiong’er Group immediately to the south of the Qianhe gold deposit and along the Machaoying Fault (Fig. 1). It is composed of four intrusive units that have similar composition. These are fine-, medium- and coarse-grained porphyritic biotite monzonite and fine-grained biotite syenogranite, with zircon U–Pb ages ranging from 148.2 to 127.2 Ma (Guo et al. 2009; Gao et al. 2010; Mao et al. 2010). The age data confirm that the Heyu pluton was produced by multiple episodes of magmatism. A recent geochemical study shows that the Heyu pluton was generated from partial melting of ancient basaltic lower crust in an extensional setting (Guo et al. 2009). Several granite to syenogranite dykes intrude both the Heyu pluton and the adjacent andesite of the Xiong’er Group. Dikes in the Qianhe mine are in general strongly altered forming secondary K-feldspar, pyrite, sericite, and quartz. The Xiong’ershan area also hosts a number of porphyritic granite to granodiorite stocks, many of which are Mo mineralized forming economically important deposits, including the world-class Leimengou (Fig. 1), Shangfanggou and Nannihu Mo deposits (Li 2005). These deposits have molybdenite Re–Os ages of 157–136 Ma (Li et al. 2003a, 2006a).
A number of WNW- and NE-striking faults are developed in the Xiong’ershan area (Mao et al. 2002; Yan et al. 2005). The WNW-trending Machaoying Fault is more than 200 km long and 5 km wide, and dips 50–80° to NNE (Yan et al. 2005; Han et al. 2009). Interpretation of geophysical data suggests that the Machaoying Fault is a transcrustal fracture penetrating into the lithospheric mantle (Yan et al. 2005). To the north of the Machaoying Fault, there are a number of NE-trending secondary or higher-order faults (Fig. 1). To the northwest of the area, the Luoning Fault separates late Mesozoic sedimentary sequences from Archean metamorphic rocks (Qi and Li 2005). The Machaoying and Luoning Faults are considered to have played an important role in the formation and distribution of gold deposits in the area (Fig. 1; Chen and Fu 1992).
Mineralization and alteration
The Qianhe gold deposit (33°59′32″ to 33°59′58″N, 111°51′46″ to 111°52′36″E), about 45 km southwest of the Songxian County, Henan Province, was discovered in the early 1980s. Mineralization is hosted in andesite and, less significantly, rhyolite and dacite of the Xiong’er Group. Orebodies are largely restricted to alteration zones developed along the WNW-striking F4 fault and its secondary structures (Figs. 2 and 3). The F4 fault is approximately 3,800 m long and 5–30 m wide, striking from 275–290° and dipping 55–75° to NNE or NNW. Protomylonite, cataclasite, fault breccias, and fault gouge are well developed in the fault, indicating multiple deformational events under different structural regimes (Zhang et al. 2006; Han et al. 2009).
The deposit consists of six orebodies, and the mineralization features can be best represented by the largest no. I orebody. This orebody strikes 95–110° and dips 58–76° to NE, and is approximately 830 m long, 1.5 to 15 m thick, continuous for more than 320-m-down plunge from the 520- to 200-m elevations (Fig. 3). It exhibits vertical variations in morphology, pattern, and texture, and is locally displaced by post-mineralization faults (Fig. 3a). Gold ores consist of quartz–sulfide veins and stockworks (Fig. 4a) and, less significantly, sulfide disseminations in alteration assemblages (Fig. 4b). Most quartz–sulfide veins occur in the shallow levels, whereas sulfide disseminations tend to be present at lower levels. Individual veins are mostly 30 to 80 cm wide and commonly show laminated textures marked by multiple pyrite veins or stringers in quartz (Fig. 4a). Fracture-veining textures (Fig. 4a, c) indicate syn-mineralization deformation.
Pyrite is the predominant sulfide mineral, but minor galena and sphalerite and trace amounts of chalcopyrite, molybdenite, argentite, and arsenopyrite are also present (Figs. 5a–d). Barite, scheelite, apatite, rutile and other minor or trace minerals are included in, or coexist with, pyrite (Figs. 5e, f). Gold occurs as native gold and electrum. Native gold commonly forms anhedral grains included in pyrite and quartz, along boundaries between or within microfractures of these two minerals (Figs. 5g, h). Electrum typically occurs as stringers or irregular inclusions within sulfides or quartz (Fig. 5i). Electron microprobe analyses show that native gold consists of 83–96 wt% Au and 4.4–16.5 wt% Ag, corresponding to a gold fineness of 835–956, whereas the electrum has 54–79 wt% Au and 20–46 wt% Ag, with a gold fineness of 541–796 (Ba et al. 2006).
Hydrothermal alteration is well-developed and largely controlled by the F4 fault zone (Figs. 2 and 3). The alteration zone ranges in width from 10 to 50 m and contains variable amounts of disseminated pyrite and other metallic minerals. The alteration involved a combination of silicification, sericitization, pyritization, and carbonatization (Fig. 6). Potassic alteration, chloritization, and epidotization are also recognized (Figs. 6a, b, e, f). Potassic alteration is characterized by the presence of disseminated or massive K-feldspar distributed in strongly altered rocks or as irregular K-feldspar veins marginal to quartz veins (Figs. 4a, 6a, b, d, e). K-feldspar grains may be variably replaced by sericite or kaolinite (Figs. 6a, b). Silicification occurs as quartz veins and stockworks, or as quartz aggregates coexisting with sericite and pyrite (Figs. 4b and 6a, c). Sericite is the second most common alteration mineral in mineralized zones and frequently associated with pyrite and quartz (Fig. 6b, c). Chloritization and epidotization are developed in andesites of the Xiong’er Group, generally distal to orebodies (Fig. 6e, f). Carbonization is widespread and represents the late stage of hydrothermal evolution, as indicated by calcite veinlets crosscutting quartz veins and other alteration phases (Fig. 6d, e). Skarn-like assemblages consisting of garnet, epidote, diopside, actinolite, and magnetite, overprinted by pyrite and calcite, are locally present in the western portion of the alteration zone (Wang et al. 2008a). Gold is closely related to the quartz + sericite + pyrite alteration assemblage.
Three hydrothermal stages can be recognized based on field and petrographic relations (Fig. 7). The first-stage (stage I) formed milky, massive quartz, K-feldspar, and skarn-like minerals. Rare metallic minerals associated with this stage include rutile, scheelite, arsenopyrite, and molybdenite. The second stage (stage II) is best represented by the quartz + sericite + pyrite assemblage and pyrite veins filling fractures in quartz of stage I. Other sulfide minerals and gold also formed predominantly in this stage. Calcite and lesser amounts of fluorite characterize the last stage (stage III).
Samples and analytical methods
Fluid inclusion microthermometry
Fluid inclusion study was conducted for four quartz samples collected from the no. I orebody. Quartz from these samples is intergrown with pyrite and considered as product of mineralizing stage II. Polished thin sections were examined under transmitted light to identify the shape, size, phase, distribution and possible origin of fluid inclusions. Microthermometric measurements were conducted using a British Linkham THMS-600 heating–freezing stage on an Olympus BX51 microscope. The uncertainties for the measurements are ±0.5, ±0.2, and ±2 °C for runs in the range of −120 to −70, −70 to 100, and 100 to 600 °C, respectively. Laser Raman spectroscopic analyses of selected inclusions were carried out with a British Renishaw 1000 Laser Raman spectrometer with a 514-nm Ar-ion laser as the source of excitation.
LA-ICP-MS zircon U–Pb dating
Gold orebodies are spatially associated with the Heyu pluton and a number of granitic dikes, dating of the pluton and dikes and ore-related alteration minerals therefore provide age constraints on gold mineralization and examine the possible genetic relationships between ore formation and granitic magmatism. Previous studies have obtained precise zircon U–Pb ages for the Heyu pluton (Gao et al. 2010; Mao et al. 2010), but the ages of the granitic dikes spatially related to gold orebodies are unknown. Two samples (Q29-1, Q30-19), each from different dikes, were collected for U–Pb dating. Zircons were separated using conventional heavy-liquid and magnetic techniques and then screened under a binocular microscope. Representative grains were mounted in an epoxy resin disk, polished, cleaned, and gold coated. Prior to isotopic analysis, all zircon grains were examined and photographed under transmitted- and reflected-light, and then imaged by cathodoluminescence (CL) to reveal their internal structures.
Zircon U–Pb dating was conducted by LA-ICP-MS at the State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan. Detailed operating conditions have been described in Liu et al. (2008a). A GeoLas 2005 laser ablation system was connected to an Agilent 7500a ICP-MS instrument. Off-line selection and integration of background and analytical signals, and time-drift correction and quantitative calibration for trace element analyses and U–Pb dating were performed using ICPMSDataCal (Liu et al. 2008a; Liu et al. 2010). Zircon 91500 was used as an external standard for U–Pb dating, and was analyzed twice every five unknown analyses. Time-dependent drifts of U–Th–Pb isotopic ratios were corrected using a linear interpolation (with time) for every five analyses according to the variations of 91500 (i.e., 2 zircon 91500 + 5 samples + 2 zircon 91500) (Liu et al. 2010). Preferred U–Th–Pb isotopic ratios used for 91500 are from Wiedenbeck et al. (1995). Uncertainty of preferred values for the external standard 91500 was propagated to the ultimate results of the samples. Concordia diagrams and weighted mean calculations were made using Isoplot/Ex_ver 3 (Ludwig 2003).
Re–Os and 40Ar/39Ar dating
Two samples, QHN02 and QHN04, were taken from underground sites for molybdenite separation. Molybdenite from both samples coexists with quartz, pyrite, and minor amounts of galena, sphalerite, or chalcopyrite. Field relationships indicate that molybdenite in both samples represents the first stage of mineralization. The Carius tube method was used for dissolution of molybdenite and equilibration of the sample and tracer Re and Os (Selby and Creaser 2001). Approximately 22–23 mg of molybdenite were dissolved and equilibrated with a known amount of 185Re and isotopically normal Os at 240 °C for a 24-h period. Solvent extraction and microdistillation was used to isolate Os, whereas anion exchange chromatography was used to isolate Re (Selby and Creaser 2001). The concentrations of 187Re and 187Os were determined at the Northern Centre for Isotopic and Elemental Tracing Facility, Durham University, using isotope dilution-negative thermal ionization mass spectrometry (ID-NTIMS). Isolated and purified Re and Os solutions were loaded onto Ni and Pt filaments, respectively, for analysis by a Thermo Finnigan TRITON mass-spectrometer using Faraday collectors. Rhenium and Os concentrations and Re–Os ages were calculated using uncertainties in Re and Os mass-spectrometer measurements, spike and standard Re and Os isotopic compositions, calibration uncertainties of 185Re and 187Os and weighing uncertainties. Ages were calculated using the decay constant 187Re = 1.666 × 10−11 year−1 of Smoliar et al. (1996).
40Ar/39Ar dating was conducted on hydrothermal sericite separated from two samples belonging to the pyrite + quartz + sericite assemblage in the no. I orebody at the 240-m elevation that are interpreted as representing mineralization stage II. Based on petrographic examination, suitable parts of the samples were crushed, repeatedly sieved to obtain uniform grains (0.5–1.5 mm), cleaned in distilled water in an ultrasonic bath for 1 h, and dried. Sericite separates were then handpicked under a binocular microscope. The mineral separates were irradiated along with the ZBH-2506 standard (132.7 ± 0.1 Ma; Wang 1983) for 54 h at the 49-2 reactor, Beijing. After a 4-month cooling period, the samples were analyzed by the 40Ar/39Ar laser heating method using a GV5400 mass spectrometer equipped with a MIR10-50W CO2 laser. The analytical procedures are described in Qiu and Jiang (2007). Argon gas was extracted at consecutively higher laser powers. The released gases were purified by two Zr–Al getter pumps operated for 5 to 8 min at room temperature and ca. 450 °C, respectively. The background of the sample hold was lower than 2 mV, which is considerably lower than the signals obtained for the gas fractions (40–200 mV), and thus ensuring precise isotope analyses for the unknown. The 40Ar/39Ar dating results were calculated and plotted using the ArArCALC software of Koppers (2002). All dates are reported using 5.543 × 10−10 year−1 as the total decay constant for 40K (Steiger and Jäger 1977), and the values for the reactor correction factors are 8.984 × 10−4 for (39Ar/37Ar) Ca, 2.673 × 10−4 for (36Ar/37Ar) Ca, and 5.97 × 10−3 for (40Ar/39Ar) K. The J factors used in the age calculations are 0.0091530 ± 0.0000458 and 0.0092230 ± 0.0000461, respectively.
Stable isotopes
Three samples were collected from the no. I orebody for quartz separation. All samples consist of variable mounts of quartz, pyrite, sericite, galena, and sphalerite that precipitated from the main mineralization stage. The hydrogen and oxygen isotopes of quartz were measured at the Stable Isotope Laboratory of the Institute of Mineral Resources, Chinese Academy of Geological Sciences (CAGS). Hydrogen isotope ratios of bulk fluid inclusions in quartz were measured by mechanically crushing quartz grains of about 5 g, approximately 1 mm in size, according to the method described by Simon (2001). Samples were first degassed of labile volatiles and secondary fluid inclusions by heating under vacuum to 120 °C for 3 h. The subsequently released water was trapped, reduced to H2 by zinc at 410 °C (Friedman 1953), and then analyzed with MAT-253 mass spectrometer, Analyses of standard water samples suggest a precision for δD of ±3 ‰ (1σ). Oxygen was liberated from quartz by reaction with BrF5 (Clayton and Mayeda 1963) and converted to CO2 on a platinum-coated carbon rod. The δ 18O determinations were made on a MAT-253 mass spectrometer. The reproducibility for pure, isotopically homogeneous quartz is about ±0.2 ‰ (2σ) (Li et al. 2010a).
Four pyrite and one galena samples were selected for sulfur isotope analysis. Pyrite and galena grains from the main mineralization stage were handpicked under a binocular microscope. Contamination of mineral separates by other minerals was minimized by selecting coarse-grained grains. The sulfur isotopic analyses were conducted at CAGS, using a conventional off-line method. Approximately 15 mg of pyrite or galena were homogenized with 150 mg of Cu2O, combusted at 1050 °C for 15 min under vacuum for a quantitative conversion to sulfur dioxide (SO2) and analyzed for sulfur isotope composition on a MAT 251 mass spectrometer. The sulfur isotope results are generally reproducible within ±0.2 ‰ (2σ).
Results
Fluid inclusions
The gold-bearing quartz grains contain abundant primary fluid inclusions, which generally have negative crystal, oval or round shapes, with minor strip, triangular and irregular varieties. Individual inclusions range in size mostly from 2 to 10 μm. Three types of inclusions are recognized on the basis of phases at room and subzero temperatures, textural relationships and laser Raman spectroscopic results (Fig. 8): one-phase aqueous inclusions (type 1), two-phase aqueous inclusions (type 2), and three-phase CO2-rich inclusions (type 3). Type 1 inclusions are commonly 2–4 μm in diameter, liquid only, and composed predominantly of H2O (Fig. 8a). Type 2 inclusions primarily have oval and negative crystal forms, and range from 4 to 7 μm in diameter (Figs. 8b–e). Individual inclusions consist of liquid H2O and H2O-dominated vapor, and the vapor accounts for less than 50 % of the total volume. Type 3 inclusions are locally present and contain liquid H2O, liquid CO2, and CO2-dominated vapor. They range in size from 10 to 15 μm and have negative crystal forms (Fig. 8f).
Types 1 and 3 inclusions are too small or rare to be used for microthermometric measurements. The microthermometric data and calculated parameters for type 2 inclusions are summarized in Appendix 1 and depicted in Fig. 9. These inclusions have ice-melting temperatures (T m,ice) between −18.3 and −3.7 °C and total homogenization temperatures of 160 to 305 °C, with two peaks at 200–240 and 280 °C. All inclusions were finally homogenized into a liquid phase. Their salinities range from 6.1 to 21.8 wt% NaCl equivalent, calculated with T m,ice values and the equations of Hall et al. (1988). Using the equations of Zhang and Frantz (1987), bulk densities of the ore fluids are estimated to be 0.8–1.0 g/cm3. The Raman spectroscopic results show that both the liquid and vapor phases are dominated by H2O, with minor amounts of CO2 and traces of CH4 in the vapor phase (Fig. 10).
Zircon U–Pb ages
Zircon U–Pb isotope data are presented in Appendix 2, and the U–Pb concordia diagrams are shown in Fig. 11. Zircon grains from both samples are euhedral to subhedral, 100–160 μm long, with aspect ratios of 1.5 to 2.5, and commonly characterized by oscillatory zoning. They have high Th and U contents (>500 ppm), with Th/U ratios ranging from 0.49 to 1.32 (Q29-1) and 0.31 to 0.68 (Q30-19) (Appendix 2), typical of magmatic zircons. Fifteen spot analyses on 15 zircon grains from sample Q29-1 yield concordant ages with a weighted mean 206Pb/208U age of 132.6 ± 0.7 Ma (Fig. 11). A total of 15 spot analyses were made on 15 zircon grains for sample Q30-19. Fourteen grains are concordant, with the remaining one being slightly discordant (Fig. 11). However, the discordant analysis has a 206Pb/208U age indistinguishable from the concordant ones (Appendix 2), indicating that the discordance reflects uncertainties related to 207Pb measurement and common Pb correction, rather than lead loss. All 15 analyses give a weighted mean 206Pb/208U age of 132.8 ± 0.6 Ma (1σ). The U–Pb ages of both samples are interpreted as the time of crystallization of the granitic dikes in the mine.
Re–Os and 40Ar/39Ar ages
Two molybdenite separates contain 30.2–33.9 ppm Re and 42.6–47.9 ppb 187Os, and have similar Re–Os model ages of 134.5 ± 0.6 and 134.7 ± 0.6 Ma (2σ; Table 1). The ages are interpreted as the crystallization age of the molybdenite.
40Ar/39Ar data of sericite separates are summarized in Appendix 3, and the apparent age spectra are illustrated in Fig. 12. Sample QH29 has a well-defined plateau age of 127.0 ± 1.6 Ma, comprising 12 continuous steps that account for 90 % of the total 39Ar released. The initial two heating steps have younger apparent ages with larger errors corresponding to smaller percentages of radiogenic 40Ar, indicating very minor argon loss in the outermost part of the mineral after its crystallization. The plateau age is within errors of the integrated age (equivalent to a K–Ar age; 125.2 ± 1.2 Ma), confirming that the sample contained no excess argon. Sample Q240 is characterized by an ascending spectrum with younger apparent ages at the low to medium temperature steps, indicating minor argon loss. The spectrum reaches a plateau consisting of eight high temperature steps, with a plateau age of 123.8 ± 1.3 Ma. The integrated age (119.0 ± 1.2 Ma) is slightly younger than the plateau age, consistent with minor argon loss as indicated by the shape of the apparent age spectrum.
Stable isotopes
Hydrogen and oxygen isotopes
Hydrogen and oxygen isotope data of gold-bearing quartz samples are listed in Appendix 4 and plotted in Fig. 13. Hydrogen and oxygen isotope data of the Qiyugou breccia pipe gold deposit from the western Xiong’ershan Area (Fig. 1), which is contemporaneous with the Qianhe gold deposit, are also included in Fig. 13. Quartz separates have δ 18OV-SMOW values of 10.8 to 11.5 ‰, whereas fluid inclusion waters extracted from quartz have δDH2O values ranging from −80 to −72 ‰. The δ 18OV-SMOW values of ore fluids were calculated using the quartz–water equilibrium function of Clayton et al. (1972), assuming a mineralizing temperature of 280 °C based on the final homogenization temperatures of primary fluid inclusions (Fig. 9). The calculations yield δ 18OV-SMOW of 3.1 to 3.8 ‰ for the mineralizing fluids (Appendix 4), which is consistent with results of previous studies (4.4 to 5.0 ‰; Li et al. 1999; Yan et al. 2005). In the δ 18O vs. δD diagram (Fig. 13), the samples plot in an area transitional from the magmatic field to the meteoric line, but in closer proximity to the magmatic component.
Sulfur isotopes
Two pyrite separates have δ 34S values of 0.26 and −0.08 ‰, whereas the other two have negative values of −6.7 and −10.6 ‰, respectively (Appendix 4). One galena sample has a more negativeδ 34S value of −16.3 ‰. Several previous studies reported similar sulfur isotope compositions for pyrite, with δ 34S values ranging from −14.8 to 2.8 ‰ (Appendix 4; Fig. 14; Anonymous (2002) The exploration report of Qianhe gold deposit, Henan Province, in Chines, unpublished; Lu et al. 2003; Yan et al. 2005).
Discussion
Timing of mineralization
Molybdenite Re–Os chronometer is remarkably robust due to the high closure temperature of Re–Os isotopes in molybdenite (Suzuki et al. 1996; Stein et al. 2001). Thus, Re–Os dating of this mineral commonly provides reliable constraints on the timing of ore formation (Selby et al. 2002). Two molybdenite separates from the Qianhe gold deposit, which are closely associated with gold-bearing pyrite, have reproducible Re–Os model ages of 134.7 ± 0.6 and 134.5 ± 0.6 Ma (Table 1), providing the first reliable constraints on the age of the Qianhe gold deposit.
Field and petrographic relations (Fig. 6c) indicate that sericite is closely related to gold mineralization, and thus 40Ar/39Ar dating of sericite provides additional constraints on the timing of hydrothermal alteration and gold deposition. Two sericite samples have broadly consistent plateau ages (Fig. 12), which are interpreted as the cooling age of the samples below the closure temperature of argon diffusion in white mica (300–350 °C; McDougall and Harrison 1999). Microthermometric measurements of primary fluid inclusions from auriferous quartz samples yielded final homogenization temperatures mostly between 300 and 200 °C (Fig. 9), lower than the argon closure temperature for white mica at moderate cooling rates (McDougall and Harrison 1999). Consequently, the sericite 40Ar/39Ar ages can also be considered as the mineralization age for the Qianhe gold deposit. Thus, the present Re–Os and 40Ar/39Ar ages may indicate two discrete mineralizing events in the early Cretaceous. Two separate mineralizing events are consistent with the multiple episodes of intrusive magmatism recorded by the Heyu pluton (see below).
The difference between the Re–Os and 40Ar/39Ar ages can also be explained to reflect a slow cooling history of the mineralizing system from ca. 135–134 Ma (molybdenite Re–Os ages) to 127–124 Ma (sericite 40Ar/39Ar ages). Alternatively, the 40Ar/39Ar ages may simply represent resetting of the K–Ar system in sericite that was crystallized at 135–134 Ma. Samples from the northern and central parts of the Heyu Pluton (Fig. 1) have concordant U–Pb ages of 134.5 ± 1.5 Ma (Guo et al. 2009) and 127.2 ± 1.1 Ma (Mao et al. 2010), which are equivalent to the present Re–Os and 40Ar/39Ar ages, respectively. It is inferred that either gold mineralization was related to the early magmatism and then disturbed by the late-stage intrusion, or that the gold deposits were generated by two separate hydrothermal events related to the repeated magmatic pulses. Two granitic dikes emplaced at ca. 132–133 Ma in the mining area are broadly contemporaneous with the early intrusion of the Heyu Pluton, and are considered to be genetically related to gold mineralization (see below).
A possible magmatic affinity
The fluid inclusions in quartz samples from the main mineralization stage have salinities ranging from 22 to 6 wt% NaCl equivalent with an average of 15.3 wt% NaCl equivalent (Fig. 9). The values are much higher than salinities of metamorphic fluids responsible for lode gold deposits in many Precambrian cratons worldwide (Groves et al. 1998; Goldfarb et al. 2005; Klein et al. 2008), but are consistent with a magmatic component (Lang and Baker 2001; Baker et al. 2006). The hydrogen and oxygen isotopes of auriferous quartz samples from the Qianhe deposit plot close to the magmatic field in the δD versus δ 18OSMOW diagram, and are comparable with ore samples of the Qiyugou breccia pipe gold deposit (Fig. 13). The Qiyugou deposit (Fig. 1) has a molybdenite Re–Os isochron age (135.6 ± 5.6 Ma; Yao et al. 2009) identical to the Re–Os ages of the Qianhe gold deposit, indicating that they formed in the same metallogenic event. Field and petrographic relations indicate an early, middle, and late stages for the Qiyugou deposit, with gold being precipitated in the first two stages (Chen et al. 2009). Fluid inclusion and stable isotope data confirm that ore fluids of the early stage were dominated by a magmatic component, with addition of meteoric water in the middle and late stages (Chen et al. 2009; Fan et al. 2011). The similar δD and δ 18OSMOW values between the Qianhe gold deposit and the middle-stage samples of the Qiyugou deposit (Fig. 13) provide additional argument for a magmatic source of the ore fluids generating the Qianhe gold deposit.
Six pyrite separates have δ 34S values close to zero (Appendix 4; Fig. 14), indicating a deep-seated, most likely magmatic source for the sulfur (Ohmoto 1972). On the other hand, other pyrite and galena samples have negative δ 34S values ranging from −16.3 to −6.7 ‰ (Fig. 14). The negative isotopic values either reflect a sulfur source from an anoxic environment or isotopic fractionation in the evolution of the mineralizing fluids. Because no organic sulfur has been found from any lithological unit in the Xiong’ershan area, we suggest that the negative δ 34S compositions are unlikely a source characteristic, rather they are most probably related to oxidation of the ore fluid system. The presence of barite, scheelite, pargasite, and apatite (Fig. 5e, f) confirm oxidizing conditions in the ore fluids in the early stage of mineralization. The proposed fluid oxidation can be explained by extensive interaction of hydrothermal fluids with the Fe2+-rich andesite in the Xiong’er Group, as indicated by pervasive alteration in and around the orebodies (Figs. 2–4). Such interactions are linked to the consumption of reduced aqueous S in the formation of pyrite and oxidation of the mineralizing fluids (Lambert et al. 1984). As a consequence of fluid oxidation, the residual fluids, and thus the sulfide minerals precipitated from the fluids, would be 32S-enriched, accounting for the negative δ 34S values. Collectively, the δ 34S data close to zero is consistent with a magmatic source, whereas the negative δ 34S values are the result of fluid oxidation. The compatible molybdenite Re–Os ages for gold ores (134.5–134.7 Ma; Table 1) and zircon U–Pb age for granitic dikes (132.6–132.8 Ma; Fig. 11) in the mining area and one biotite monzogranite sample form the Heyu pluton (134.5 Ma; Guo et al. 2009) are also consistent with a magmatic origin of the Qianhe gold deposit. Both the granitic dikes and andesites of the Xiong’er Group close to the dikes were intensively altered forming sericite + quartz + sulfide assemblages, indicating magmatic devolatization associated with the emplacement of the dikes and, by inference, the Heyu pluton. Widespread skarn-like assemblages in the western segment of the Qianhe deposit, consisting of garnet, epidote, diopside, actinolite, magnetite, pyrite and calcite, may have also resulted from metasomatism of the Paleoproterozoic andesites by a magmatic fluid (Wang et al. 2008a).
The synchronicity of the regional magmatism and mineralization provide an additional argument for a magmatic derivation of the ore fluids and other components. Geochronological data have revealed that pervasive Au, Mo, and Ag–Pb–Zn mineralization throughout the Xiong’ershan area (Fig. 1) occurred predominantly in the 145 to 115 Ma interval (Wang et al. 2001; Li et al. 2003a; 2005; Qi and Li 2005; Han et al. 2007; Mao et al. 2008a; Yao et al. 2009; Zhou et al. 2009), coincident with the emplacement of granitic intrusions and numerous mineralized porphyry stocks in the area (158–110 Ma; Li 2005; Wang et al. 2005; Han et al. 2007; Mao et al. 2008a; Ye et al. 2008; Guo et al. 2009; Gao et al. 2010). Extensive magmatism could have provided sufficient heat energy, fluids and other components contributing to the formation of gold and other types of deposits throughout the area.
Regional synthesis and geodynamic setting
Immediately to the west of the Xiong’ershan area, the Xiaoqinling area (Fig. 15a) contains more than 40 gold deposits with proven gold reserves of approximately 800 t (Yang et al. 2003). Previous Re–Os and 40Ar/39Ar dating indicates that the Dongchuang, Hongtuling, and Quanjiayu gold deposits formed between 132 and 127 Ma (Xu et al. 1998; Wang et al. 2002; Li et al. 2007). More recently, Li et al. (2012a, b) provided a comprehensive geochronological study on major gold deposits in Xiaoqinling, bracketing their formation in the range of 154–119 Ma. These data thus indicate synchronous gold deposition in the Xiong’ershan and Xiaoqinling areas. Gold mineralization in both areas is coeval with the emplacement of the Xiaoqinling metamorphic core complex (135–123 Ma; Zhang and Zheng 1999) and intrusion of many mafic dikes and A-type granites (141–117 Ma; Ye et al. 2008; Zhou et al. 2008; Mao et al. 2010; Wang et al. 2011; Li et al. 2012b), indicating that gold deposits both in the Xiong’ershan and Xiaoqinling areas formed in an extensional setting.
Early Cretaceous lode gold deposits are also widespread in the Jiaodong gold province and other parts of the eastern NCC (Fig. 15a) (Pei 1998; 2003; Mao et al. 2008b). The Jiaodong district (Fig. 15a) is the largest gold repository in China, containing proven reserves of >1,000 t Au (Qiu et al. 2002). Recent detailed geochronlogical studies have demonstrated that a majority of the gold deposits were emplaced at approximately 120 Ma (Yang et al. 2000; Li et al. 2003b, 2006b), with a few deposits having ages of 108–107 Ma (Li et al. 2006b). Gold veining in Jiaodong was accompanied with the emplacement of numerous mafic dikes and fault–basin formation, indicating an extensional setting for gold mineralization (Davis et al. 2002; Ren et al. 2002; Liu et al. 2006a, 2008b; Mao et al. 2008b; Tan et al. 2008; Li et al. 2011; Zhang et al. 2011). A large number of Au, Mo (Cu), and skarn Fe (Cu) deposits in the northern margin of the NCC (Fig. 15a) have ages of 148–112 Ma (Huang et al. 1996; Wei et al. 2001; Yu and Mao 2004; Mao et al. 2005; Zheng et al. 2007; Wang et al. 2008b). The broadly contemporaneous mineralization in the southern, eastern and northern parts of the NCC strongly suggests a craton-wide gold metallogenic event under consistent geodynamic setting (Fig. 15b).
After prolonged stabilization since its formation in the late Peleoproterozoic (Zhao et al. 2009), the NCC was significantly reactivated in the Mesozoic as indicated by extensive magmatism (Guo et al. 2001; Wu et al. 2005; Zhang et al. 2005; Gao et al. 2008). Many zircon U–Pb geochronological studies have shown that the magmatism took place mostly in the late Jurassic to early Cretaceous (158–120 Ma), an event interpreted in terms of extension or thinning of the subcontinental mantle lithosphere beneath the NCC (Xu et al. 2004; Wu et al. 2005; Mao et al. 2010; Yan et al. 2010). Lithospheric extension of the NCC is further illustrated by the development of numerous metamorphic core complexes (Davis et al. 2002; Liu et al. 2006b, 2008c; Zhu et al. 2007, 2010) and intra-continental rift basins (Tian et al. 1992; Ren et al. 2002), with the former being precisely dated at 130–110 Ma (Zhang and Zheng 1999; Davis et al. 2002; Liu et al. 2005; Yang et al. 2007). Recent geophysical data provide more compelling evidence for a loss of at least 80–120 km of the lithosphere beneath the eastern NCC (Chen et al. 2008b). We therefore conclude that pervasive gold mineralization throughout the eastern NCC was ultimately controlled by the removal and thinning of mantle lithosphere beneath the craton. The mechanism of this lithospheric thinning event is debatable, but may have involved delamination of the lithosphere associated with upwelling of asthenosphere during the late Mesozoic when the paleo-Pacific plate was westerly subducted underneath the eastern Eurasian continent (e.g., Wu et al. 2005; Mao et al. 2011, 2012).
Conclusions
The Qianhe gold deposit formed at intermediate temperature (160–305 °C) from moderately saline fluids with salinities of 22–6 wt% NaCl equivalent. Molybdenite Re–Os and sericite 40Ar/39Ar dating revealed that the Qianhe gold deposit either formed by two separate mineralizing events at 135–134 and ca. 127 Ma, or was thermally disturbed by post-mineralization processes after its formation at 135–134 Ma. Hydrogen and oxygen isotopes of auriferous quartz and sulfur isotopes of sulfide minerals, together with the U–Pb ages of granitic intrusions spatially associated with gold orebodies, favor a possible magmatic derivation for the ore fluids and sulfur.
Gold and polymetallic deposits of similar ages are widespread in several other major orefields along the southern, eastern, and northern edges of the NCC, revealing a craton-wide, relatively short-lived, metallogenic event. This event is temporarily coincident with extensive magmatism, formation of rifted-basins, and development of metamorphic core complex over the NCC, all pointing to extension and reactivation of the NCC. Thus, it is concluded that large-scaled mineralization in the Xiong’ershan area and throughout the eastern NCC was controlled by cratonic reactivation.
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Acknowledgments
Financial support for this research was provided by the Natural Science Foundation of China (grants 90814004 and 40821061), the Fundamental Research Funds for the Central Universities (CUG120102), and the MOST special fund from the State Key Laboratory of Geological Processes and Mineral Resources (MSFGPMR201205). Prof. Huaning Qiu is thanked for his expert suggestions in the course of 40Ar/39Ar dating. Zhanke Li and Zhiyuan Ren are thanked for their assistance in the field and during lab work. We are indebted to Mr. Kuang Gongming from the Jinniu Gold Company for his logistic support during our stay at the mine. We thank Prof. Jinwen Mao and an anonymous reviewer for their thorough review and comments that have been very helpful in our revision. Our special thanks go to Prof. Bernd Lehmann for his constructive suggestions in improving the presentation of the paper.
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Appendix 1
Microthermometric data and calculated parameters for fluid inclusions of the Qianhe gold deposit. (XLS 36 kb)
Appendix 2
LA-ICP-MS zircon U–Pb isotope data for granitic dikes from the Qianhe gold deposit. (XLS 36 kb)
Appendix 3
40Ar/39Ar data of hydrothermal sericite from the Qianhe gold deposit. (XLS 36 kb)
Appendix 4
Hydrogen, oxygen, and sulfur isotope data of the Qianhe gold deposit. (XLS 32 kb)
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Tang, KF., Li, JW., Selby, D. et al. Geology, mineralization, and geochronology of the Qianhe gold deposit, Xiong’ershan area, southern North China Craton. Miner Deposita 48, 729–747 (2013). https://doi.org/10.1007/s00126-012-0451-2
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DOI: https://doi.org/10.1007/s00126-012-0451-2