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Article

Constraints on the Petrogenesis and Metallogenic Setting of Lamprophyres in the World-Class Zhuxi W–Cu Skarn Deposit, South China

by
Wei Zhang
1,
Shao-Yong Jiang
1,*,
Tianshan Gao
2,
Yongpeng Ouyang
3 and
Di Zhang
1
1
State Key Laboratory of Geological Processes and Mineral Resources, Collaborative Innovation Center for Exploration of Strategic Mineral Resources, School of Earth Resources, China University of Geosciences, Wuhan 430074, China
2
Nanjing Geological Survey Center, China Geological Survey, Nanjing 210016, China
3
912 Party of Jiangxi Bureau of Geology and Mineral Exploration, Yingtan 335001, China
*
Author to whom correspondence should be addressed.
Minerals 2020, 10(7), 642; https://doi.org/10.3390/min10070642
Submission received: 16 May 2020 / Revised: 17 July 2020 / Accepted: 17 July 2020 / Published: 20 July 2020
(This article belongs to the Special Issue Magmatic–Hydrothermal Alteration and Mineralizing Processes)
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Abstract

:
Whole-rock and apatite geochemical analyses and zircon U–Pb dating were carried out on the lamprophyres in the world-class Zhuxi W–Cu skarn deposit in northern Jiangxi, South China, in order to understand their origin of mantle sources and their relationship with the deposit, as well as metallogenic setting. The results show the lamprophyres were formed at ca. 157 Ma, just before the granite magmatism and mineralization of the Zhuxi deposit. These lamprophyres have from 58.98–60.76 wt% SiO2, 2.52–4.96 wt% K2O, 5.92–6.41 wt% Fe2O3t, 3.75–4.19 wt% MgO, and 3.61–5.06 wt% CaO, and enrichment of light rare earth elements (LREE) and large-ion lithophile elements (LILE), and depletion of high-field-strength elements (HFSE). Apatites in the lamprophyres are enriched in LREE and LILE, Sr, S, and Cl, and have 87Sr/86Sr ratios ranging from 0.7076 to 0.7078. The conclusions demonstrate that the lithospheric mantle under the Zhuxi deposit was metasomatized during Neoproterozoic subduction. Late Jurassic crustal extension caused upwelling of the asthenospheric mantle and consecutively melted the enriched lithospheric mantle and then crustal basement, corresponding to the formation of lamprophyres and mineralization-related granites in the Zhuxi deposit, respectively.

1. Introduction

The Yangtze and Cathaysia blocks were collided by a north-directed subduction during the Neoproterozoic (Jiangnan orogeny) [1] and together they form the South China Block. Multiple episodes of Mesozoic magmatism occurred in the South China Block, including voluminous granites associated with W deposits and subordinate bimodal volcanic rocks, mafic–ultramafic intrusions, and extensive swarms of mafic dikes [2,3,4]. Although tectonic models proposed to interpret the Mesozoic magmatism in the South China Block are controversial, it is generally accepted that the South China Block was in an extensional setting due to lithospheric thinning or back-arc extension [5,6,7,8]. Previous studies of mafic rocks show that the lithospheric mantle below the Yangtze and Cathaysia blocks is different [9]. Along the eastern boundary of the Yangtze Block, Late Jurassic high-Mg andesites in Youjiang basin have similar compositions to those of the Neoproterozoic high-Mg rocks and were derived from partial melting of the enriched lithospheric mantle metasomatized by the Neoproterozoic subduction [10]. The similar copper-rich lithospheric mantle is responsible for the formation of adakitic rocks related to the Dexing porphyry copper deposit (largest porphyry Cu deposit in South China) in northeastern Jiangxi [11].
In the world-class Zhuxi W–Cu skarn deposit (60 km northwest of the Dexing porphyry Cu deposit), lamprophyre dikes were intersected by drilling and their relationship with this deposit is unclear. Did they contribute Cu by partial melting of enriched lithospheric mantle sources or as a tectonic marker representing asthenospheric mantle upwelling, which provided the heat for partial melting of the metal-rich crustal rocks? Considering that the lithospheric mantle below the Yangtze Block was possibly metasomatized by Neoproterozoic subduction [10,11], this study conducted geochronology and whole-rock geochemistry analyses of the Zhuxi lamprophyres and obtained the composition (major elements, trace elements, and Sr isotopes) of apatite in them, in order to unravel (1) the temporal relationship between the Zhuxi lamprophyres and the ore deposit, (2) magma sources, and (3) possible volatile (F, Cl, and S) recycling processes [12] during earlier suprasubduction metasomatism.

2. Geological Setting

2.1. Regional Geology

The Zhuxi W–Cu skarn deposit is near the southeastern margin of the Yangtze Craton and located in the Jiangnan porphyry–skarn tungsten belt, which is separated from the Middle-Lower Yangtze River porphyry–skarn Cu–Au–Mo–Fe ore belt by the Yangxi-Changzhou fault ([1,13], Figure 1). The regional lithostratigraphy summarized by [13,14] is described here. The Precambrian basement consists of Mesoproterozoic Tianli schist, Neoproterozoic volcanoclastic sequences, sedimentary rocks, and ophiolitic complexes in the eastern Jiangnan Massif, and Neoproterozoic Shuangqiaoshan Group (phyllite and metavolcanoclastic rocks) in the central Jiangnan Massif. The latest Neoproterozoic Nanhua Group is on the top of this basement. The cover sequence of the Jiangnan Massif includes Silurian to Early Jurassic marine classic rocks, carbonate rocks, and paralic clastic rocks. Middle Jurassic to Cretaceous sedimentary and volcanic rocks occur along the NE-trending terrigenous rift basins ([15], Figure 1).
Intrusions in this area include Neoproterozoic and Middle to Late Mesozoic granitic rocks. The Neoproterozoic granitoids mainly occur in northwestern Jiangxi, southern Anhui, and northeastern Hunan. The Middle to Late Mesozoic granitic rocks broadly formed during two periods. The first group of granites with ages of 136–149 Ma is peraluminous–metaluminous, high-K calc-alkaline, and associated with tungsten deposits. The second group of granites with ages of 102–129 Ma are peraluminous S-type granites and are related to either tungsten or tin deposits in this region [13].

2.2. Ore Deposit Geology

In the Zhuxi deposit area, the oldest stratum is the Neoproterozoic Shuangqiaoshan Group that is composed of lower greenschist-facies phyllite, slate, and metasiltstone [16], and is covered by Middle Carboniferous Huanglong Formation (dolomite), Upper Carboniferous Chuanshan Formation (limestone), Lower Permian Xixia Formation (limestone mingled with clastic rocks), and Lower Triassic Anyuan Group (micrites, shale, and siltstones) ([17], Figure 2 and Figure 3).
Several parallel NW-trending faults controlled the occurrence of the Early Paleozoic shallow marine carbonate rock ([18], Figure 2). The F1 fault is a regional-scale fault that extends hundreds of kilometers, and F2 is the unconformity boundary between the carbonate rock and the Neoproterozoic metamorphic basement [17]. Subordinate EW-trending faults also occur.
Intrusions in the Zhuxi deposit include biotite granite, muscovite granite, granitic porphyry, and lamprophyre. The granitic porphyry crosscuts the muscovite granite. Both occur as dikes at depths of 600–2400 m below the surface and intrude the biotite granite pluton (Figure 3). The Zhuxi granites generally consist of quartz, alkaline feldspar, and minor plagioclase, biotite, and muscovite. Accessory minerals in them include zircon, apatite, and Ti/Fe oxides. Veinlet-disseminated scheelite and chalcopyrite mineralization in them is accompanied by pervasive chlorite and sericite alteration. These granites formed at ca. 153 Ma [14,19], which is contemporaneous with mineralization ages constrained by muscovite 40Ar–39Ar, molybdenite Re–Os, and U–Pb titanite [20,21]. The Zhuxi granites are highly siliceous (>70 wt%) and peraluminous, and show typical S-type granite characteristics. [14,19]. Major and trace element, as well as Sr–Nd–Hf isotopic compositions of Zhuxi granites indicate they are derived from partial melting of the Neoproterozoic Shuangqiaoshan Group in this region [14,19].
Lamprophyre dikes intruded in the Carboniferous–Permian strata are 50–500 m long and 1–10 m wide. They were intersected by drilling along exploration lines 7, 62, and 78 and show 4–15 m thickness. No direct contact between these lamprophyres and granites was found. However, presence of pervasive sulfide mineralization along fractures in some of these lamprophyres indicates the lamprophyre formed earlier than the Zhuxi granites and ore deposit. The Zhuxi lamprophyre is characterized by a porphyritic texture in which phenocrysts (30 vol.%) of amphibole and biotite are enclosed in groundmass (70 vol.%) of plagioclase, accessory apatite, titanite, and zircon. Amphibole is subhedral to anhedral. Some grains were partially replaced by biotite. Biotite is euhedral to subhedral with 10–50 μm width and 50–200 μm length and was locally altered into chlorite. Minor quartz is also found in the groundmass. Alteration minerals in the lamprophyres include chlorite, sericite, and calcite (Figure 4).

3. Analytical Methods

3.1. LA–ICP–MS Zircon U–Pb Dating

Zircon grains in the lamprophyres separated by heavy liquid were fixed in an epoxy mount and imaged by scanning electron microscopy–cathodoluminescence (SEM–CL). LA–ICP–MS zircon U–Pb dating were undertaken on a Thermo iCAP RQ ICP–MS equipped with a 193 nm RESOlution S-155 laser-ablation system at the State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan, China. Laser ablation conditions were 4 J/cm2 of laser energy, 8 Hz of ablation frequency and 33 μm of spot diameter. Zircon 91500 was used as an external standard. Details of the analytical processes were described in [22].

3.2. Whole-Rock Major and Trace Elements Analyses

The whole-rock geochemical analyses were carried out in the State Key Laboratory for Mineral Deposits Research, Nanjing University (Najing, China) by Thermo Scientific ARL 9900 X-ray fluorescence (XRF) and the analytical precisions are better than 1%. For trace element analyses, about 50 mg sample powder was dissolved in high-pressure Teflon bombs using an HF + HNO3 mixture and measured by a Finnigan Element II inductively coupled plasma mass spectrometer (ICP–MS). Rh was used as an internal standard to monitor signal drift. The analytical precisions were estimated to be better than 10% for all trace elements.

3.3. Major Elements, Trace Elements, and Sr Isotopes in Apatite

Major element analyses of apatite were performed in the Testing Center of the China Metallurgical Geological Bureau, Shandong, China, using a JEOL JXA-8230 electron microprobe analyzer (EMPA) equipped with four wavelength dispersive spectrometers. The operating conditions were 15 kV voltage, 20 nA current, and 5 μm beam size. The measurement times were 10 s for Ca and P, and 20 s for Na, Mg, Si, Fe, Mn, Sr, F, and Cl. The standards used were apatite (Ca, P), jadeite (Na, Si), diopside (Mg), olivine (Fe), rhodonite (Mn), celestite (Sr), phlogopite (F) and tugtupite (Cl). Precision for EMPA analysis was calculated from counting statistics, and was generally better than 1% for measurements >10 wt%, and better than 5% for contents >0.5 wt%.
In situ trace element analyses of apatite used a RESOlution S-155 laser ablation system coupled to a Thermo iCAP Qc inductively coupled plasma mass spectrometry (LA–ICP–MS) at the State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan, China. The NIST 612 and 610 glass standards and the USGS reference glasses (BIR-1G, BCR-2G, and BHVO-2G) were repeatedly analyzed between every four apatite samples. Both standards and samples were ablated using a 33 μm spot size, 10 Hz repetition rate, and corresponding energy density of ~3 J/cm2. The Ca measured by EPMA was used as the internal standard, whereas the USGS reference glasses noted were used for external calibrations. Data reduction was offline after analysis and was conducted by using the ICPMSDataCal software (version 11, the State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Wuhan, China ) [22].
The in situ Sr isotope ratios were determined with a NWR193 laser ablation system coupled to a Nu Plasma II MC–ICP–MS instrument at the State Key Laboratory of Geological Processes and Mineral Resources (Wuhan, China). The measurements involve correction of critical spectral interferences that include Kr, Rb, and doubly charged rare earth elements. A modern-day coral (Qingdao), well characterized for its 87Sr/86Sr isotopic composition by isotope dilution thermal ionisation mass spectrometry (ID–TIMS), was used as an external standard. The analysis conditions were 55 μm spot size, 10 Hz repetition rate, and ~11 J/cm2 energy density. The average 87Sr/86Sr ratio obtained for the coral standard was 0.70926 ± 0.00002, which is within analytical error of TIMS values of 0.70925 ± 0.00002 [23].

4. Results

4.1. Zircon U–Pb Age

Zircon grains from the Zhuxi lamprophyre are generally subhedral to euhedral, dominantly short-prismatic with a length of 50 to 100 μm. Cathodoluminescence images show that zircon typically has a dark core with a bright rim. Twelve zircon rims have 8.82–156 ppm Th, 374–1459 ppm U, with the Th/U ratios of 0.01 to 0.28. They yield a concordia age of 157.9 ± 1.5 Ma (MSWD = 0.93) and a weight mean 206Pb/238U age of 157.9 ± 1.7 Ma (MSWD = 1.9). These lamprophyre ages are slightly older than the emplacement ages of the mineralization-related granites (148–153 Ma) in the Zhuxi deposit [14,19] (Figure 5; Table 1).

4.2. Whole-Rock Major and Trace Elements

Lamprophyres are rich in volatiles and their loss on ignition (LOI) is usually high (many published data above 15 wt%; e.g., [24]). The LOI values of Zhuxi lamprophyres are very low, ranging from 2.98 to 4.37 wt%, indicating they are relatively fresh. In order to better describe the geochemical characteristics of Zhuxi lamprophyres, we collected from literature the data of mafic rocks that are temporally and spatially close to the Zhuxi lamprophyres, including the Wushan lamprophyres [25] and two mafic–ultramafic intrusions (Quzhou and Longyou) in the nearby Gan-Hang belt [4]. Compared with mafic rocks from these regions, the Zhuxi Lamprophyres have the highest SiO2 (58.98–60.76 wt%) and K2O (2.52–4.96 wt%), and the lowest TiO2 (0.93–1.01 wt%), Fe2O3t (5.92–6.41 wt%), MnO (0.08–0.1 wt%), MgO (3.75–4.19 wt%), and CaO (3.61–5.06 wt%) (Figure 6; Table 2). The Na2O and P2O5 of Zhuxi lamprophyres are similar to the Wushan lamprophyres ranging from 2.01 to 3.19 wt% and 0.44–0.49 wt%, respectively. In terms of the SiO2 versus K2O relationship, the Zhuxi lamprophyres are calc-alkaline lamprophyre (Figure 6; Table 2).
The transition element contents in the Zhuxi lamprophyres are low (e.g., V = 118–126 ppm, Cr = 90–105 ppm, Co = 17–20 ppm, and Ni = 57–65 ppm). The chondrite-normalized REE patterns of the Zhuxi lamprophyres are characterized by light rare earth element enrichment ((La/Yb)N = 25–29) and (Yb/Gd)N ratios are around 4. Their negligible negative Eu anomalies (0.8–0.9) are similar to the Wushan lamprophyres, whereas the Quzhou and Longyou mafic intrusions have positive Eu anomalies (Figure 7). The trace element compositions of the Zhuxi lamprophyres normalized to primitive mantle show enrichment in fluid mobile large-ion lithophile elements (Rb, Ba, Th, U, and K) and strong depletion in high-field-strength elements (Nb, Ta, and Ti). All samples are broadly parallel to the global subducting sediment II (GLOSS-II) [29] and are distinct from ocean island basalt (OIB; [30]) (Figure 7; Table 2) or middle ocean ridge basalt (MORB) [31].

4.3. Major and Trace Elements of Apatite

Major elements analyzed by electron microprobe analyzer of the apatites in the Zhuxi lamprophyre show CaO of 53.5–54.2 wt% and P2O5 of 39.5–40.7 wt%. The apatites also have 0.16–0.24 wt% SiO2, 0.12–0.44 wt% MgO, 0.18–0.44 wt% FeO, and 0.14–0.29 wt% Na2O. Contents of TiO2, K2O, and MnO in these apatite samples are generally below detection limits. Contents of F and Cl are 1.85–2.31 wt% and 0.37–0.57 wt%, respectively. The SO3 concentrations are from 0.79 to 1.12 wt%, indicating they are high-S apatites (>0.7 wt%) [33].
The trace element contents in the apatites from the Zhuxi lamprophyre include 18.7–28.0 ppm V, 13.0–22.1 ppm Ga, 18.8–35.2 ppm Ge. Rb is negligible and Sr content is high (4763–6080 ppm) and Y contents are from 125 to 222 ppm. U and Th range from 2.84 to 5.64 ppm and from 34.3 to 78.9 ppm, respectively. The total rare earth elements (ƩREE) contents are from 6525 to 10,864 ppm with (La/Yb)N ratios of 143 to 175 and slightly negative (Eu/Eu*)N anomalies (0.77–0.81) (Figure 8a). Primitive mantle normalized trace element diagrams show these apatites have significant depletion of high-field-strength elements (Nb, Ta, Zr, and Hf) and slight Pb and Sr depletion (Figure 8b; Table 3).

4.4. Strontium Isotopes of Apatite

Ten apatite grains were selected for Sr isotope analysis and the results indicate a relatively homogeneous 87Sr/86Sr ratio from 0.7076 to 0.7078 (Figure 9; Table 3). Considering the extremely low Rb/Sr ratios in these apatites, the measured 87Sr/86Sr represent the initial 87Sr/86Sr of the magma.

5. Discussion

5.1. Petrogenesis of the Zhuxi Lamprophyre

5.1.1. Source Mineralogy

Relatively homogeneous whole-rock geochemistry, weak negative Eu anomalies, as well as the homogeneous apatite composition (sensitive to crustal contamination; e.g., [34]) indicate assimilation of silicic upper crustal material is not significant in the Zhuxi lamprophyres. High K2O and large-ion lithophile elements (LILE) in the Zhuxi lamprophyres require phlogopite or amphibole in the source region [35], since Rb and Ba are compatible in phlogopite [36], while Rb, Sr, and Ba are moderately compatible in amphibole. Melts derived from partial melting of phlogopite-bearing rocks typically have significantly higher Rb/Sr (>0.1) and lower Ba/Rb values (<20) [37] (Figure 10a), whereas melts from amphibole-bearing sources have extremely high Ba/Rb values (>20) [37]. The Zhuxi lamprophyres with low Ba/Rb ratios (<20), but high Rb/Sr ratios (up to 0.43) indicate phlogopite in their source. Deggen et al. [38] modeled the garnet, garnet–spinel, and spinel stability field during partial melting of lherzolite. Based on the K/Yb/1000 vs. Dy/Yb diagram (Figure 10b), unlike Quzhou and Longyou mafic–ultramafic intrusions plotting in the garnet stability field, the Zhuxi and Wushan lamprophyres plot in the garnet–spinel transition field, indicating garnet and spinel are both present in the source region of Zhuxi lamprophyre, corresponding to a depth of 75–85 km [39,40,41].

5.1.2. Mantle Metasomatism by Subducted Components

The trace element compositions (Figure 7; Figure 11) of Zhuxi lamprophyres show they are very different from the ocean-island basalts (OIB) and mid-ocean-ridge basalts (MORB), but are broadly similar to average continental crust [29] and global subducting sediments-II [28]. Different La/Yb ratios between them may be attributed to different degrees of partial melting. The enrichment of large-ion lithophile elements (LILE) and depletion of high-field-strength elements (HFSE) in primitive mantle normalized diagrams are generally considered as fingerprints of subduction processes (e.g., [42,43]), during which the HFSEs are stored in minerals, including rutile and ilmenite in the subducted slab, whereas the LILEs easily transfer into the fluids [44,45]. In the Th/Yb versus Nb/Yb diagram (Figure 11b), the diagonal mantle array is defined by the averages of N-MORB, E-MORB, and OIB, and the Zhuxi and Wushan lamprophyres containing subduction components are displaced toward higher Th/Yb values. The Nb/U ratios of Zhuxi lamprophyres range from 4.86 to 5.86, much lower than those in the MORB and OIB (47 ± 7; [46,47]), and the lower crust (Nb/U ≈ 25; [48]), but are similar to the pelagic sediments [49] (Figure 11c). Thus, the enriched lithospheric mantle of the Zhuxi lamprophyres is possibly modified by subducted sediments through melts or fluids. Yang and Jiang [50] proposed various origins for lamprophyres from the Jiurui district of Middle-Lower Yangtze River Belt, and suggested Nb/Ta ratios in all major silicate Earth reservoirs are subchondritic (chondritic Nb/Ta = 19.9; [51]) and the superchondritic Nb/Ta ratios occur in subduction-related melts rather than subduction-related fluids [52,53]. The Nb/Ta ratios of Zhuxi lamprophyres are lower than 18, indicating their mantle metasomatism is likely related to the subduction-related fluids. This conclusion is also supported by their (Ta/La)N and (Hf/Sm)N ratios (Figure 11d). The depleted mantle (DM), OIB, and normal mid-ocean-ridge basalts (N-MORB) all have the (Ta/La)N and (Hf/Sm)N ratios around 1, whereas the melt-related and fluid-related subduction metasomatism, and carbonate metasomatism show different (Hf/Sm)N ratios. The Zhuxi lamprophyres with (Hf/Sm)N around 1 and (Ta/La)N of 0.10–0.15 are confined to an array of fluid-related subduction metasomatism.

5.2. Significance of Apatite Geochemistry

As discussed above, the Zhuxi lamprophyres could be a result of partial melting of the enriched lithospheric mantle that was metasomatized by the fluids released from subduction-related and pelagic-sediment-like materials. Subduction typically incorporates mobile elements into the lithospheric mantle [57,58]. This could explain the enrichment of LILE (Figure 8b) and Sr (ca. 5000–6000 ppm; Table 3) in the apatites of the Zhuxi lamprophyres. Reported Sr concentrations in basalt apatites are from 621–1066 ppm, and those in the granite apatites are much lower [59].
Volatile element (F, Cl, and S) content in mantle apatites are related to various subduction component sources. High F contents in basaltic magmas are derived from partial melting of F-rich minerals (F-phlogopite, fluoroapatite, and F-rich aragonite) in the source region. Cl and H2O are efficiently extracted from the slab, whereas F is largely returned to the deep mantle [60]. Chlorine contents in mantle-derived apatites are very heterogeneous. Metasomatic apatites are quite Cl-rich, whereas primitive apatites contain very little Cl [61]. Mantle-derived melt inclusions and volcanic glasses show the Cl concentration lower than 0.1 wt% [62,63]. Based on the Cl partition coefficient between apatite and basaltic melts of ~0.8 [64], the calculated Cl in mantle apatite is lower than 0.08 wt%. The relatively high Cl contents (0.37–0.57 wt%) of apatite in the Zhuxi lamprophyres are attributed to the addition of Cl-rich brines released by the subduction slab into their source region [62,65,66]. Sulfur solubility in melts can be enhanced by increasing fO2, temperature, and pressure. Basaltic melts typically have higher S than felsic melts [67,68]. The apatites in the Zhuxi lamprophyres belongs to high-S apatite, based on the classification of [32], and the S most likely originated from pelagic-sediment-like materials as discussed above, since in the subduction setting the pelagic clays and cherts have the highest S (1000s of ppm), whereas volcaniclastics have very low S contents (100s ppm; [69]).

5.3. Timing of Metasomatic Enrichment and Implication for Metallogenic Setting

After a tectonic transition from the Tethys regime (continental collision between the South China and Indonesian blocks) to the Pacific regime (Paleo-Pacific plate subduction) during ca. 200–180 Ma in south China [70], voluminous Jurassic to Cretaceous intrusions and subordinate volcanic rocks formed in proposed tectonic settings, including subduction of the Paleo-Pacific plate [5], lower-crustal delamination [7], intraplate lithospheric rifting [6], and a mantle plume [71]. The most popular concept is that the South China Block was under an extensional setting since the Early Jurassic ([8] and the references therein). The Zhuxi lamprophyres are coeval with the Taoxikeng lamprophyres in south Jiangxi [72] and formed at ca. 158 Ma. During this period, the voluminous W–Sn granites formed in the Nanling Range in south Jiangxi due to lithospheric thinning–extension and upwelling of asthenospheric mantle [2,3]. A contemporaneous (153–163 Ma) NNE-trending A-type granite belt in southeast Hunan and north Guangxi was suggested to have developed in an intra-arc rift or back-arc setting as a consequence of Paleo-Pacific plate slab roll-back [73]. This progressive slab rollback resulted in a coastward migration of magmatism accompanied by regional extension [74]. The Zhuxi lamprophyres, as well as the recently reported high-Mg andesites (ca. 159 Ma) at the north and south end of Jiangnan Orogen [10], support the conclusion that during the Late Jurassic to Early Cretaceous the Jiangnan Orogen was in an intra-arc rift or back-arc extension setting [75].
The Zhuxi lamprophyres were derived from the enriched mantle modified by fluid-related subduction metasomatism. Although some tectonic models suggested that the fluids were derived from the subducted Paleo-Pacific plate (e.g., [8]), it is questionable if the Paleo-Pacific plate subducted that far into the interior of the South China Block in Late Jurassic. [10] advocated that the enriched mantle below the Yangtze Block was related to an ancient metasomatism caused by amalgamation between the Yangtze Block and the Cathaysia Block (Jiangnan Orogen). This conclusion is also supported by [15] who proposed that the intrusion related to the giant Dexing porphyry copper deposit is a product of partial melting of the early Neoproterozoic relict island arcs that are Cu enriched. The Yangtze Block has a distinct enriched mantle from that of the Cathaysia Block [9]. Along the eastern border of the Yangtze Block (Jiangnan Orogen), the Late Jurassic Yangtun and Liuliang andesites as well as the Early Neoproterozoic subduction-related bonitite-series rocks [76], and high-Mg basalts [77,78] share a similar metasomatic source attributed to the Early Neoproterozoic subduction [10]. The Zhuxi lamprophyres have similar major element, trace element, and initial 87Sr/86Sr (0.7076–0.7078) compositions, indicating they are most likely derived from partial melting of the same lithospheric mantle metasomatized by fluids released from the Neoproterozoic-subducted sediments during the Jiangnan orogeny.
Although tungsten deposits are generally associated with granitoid magmas, mafic intrusions may also play a vital role in the formation of ore systems. For example, in the world-class Cantung W–Cu deposit where lamprophyres also occur, the intrusion of a hot mafic magma into a larger and cooler felsic magma chamber results in enriching the felsic melt in volatiles and metals [79]. Lamprophyres in the Zhuxi deposit formed earlier than the granites related to W mineralization; they could have substantially contributed volatiles to prolonged generation of granitic partial melts in the lower crust (i.e., [80]) and the large amount of CH4 in fluid inclusions of the Zhuxi deposit reported by [81] could be a result of mantle outgassing [82]. This conclusion is supported by [83], who speculated that aqueous fluids at Maikhura could be entirely or in part supplied from crystallizing granitoid magma, whereas high-carbonic fluids are from a mafic magma source situated at a greater depth.

6. Conclusions

The enriched lithospheric mantle below the Zhuxi W–Cu skarn deposit was metasomatized by fluids (high Cl and oxidized S) exsolved from subduction sediments during the Neoproterozoic collision between Yangtze and Cathaysia blocks (Jiangnan orogeny). Late Jurassic crustal extension in this region caused upwelling of the asthenospheric mantle accompanied by heat advection. This process resulted in partial melting of the enriched lithospheric mantle and crustal basement that formed first the lamprophyres (ca. 157 Ma) and then the mineralization-related granites (148–153 Ma) in the Zhuxi deposit. The heat offered by mafic magmas may also enhance felsic magma buoyancy and possibly modify the thermal environment into which the felsic magmas are emplaced, which facilitates more efficient fractionation of the felsic magma.

Author Contributions

Conceptualization, S.-Y.J. and W.Z.; methodology, W.Z. and D.Z.; validation, W.Z.; formal analysis, W.Z.; investigation, W.Z., T.G. and Y.O.; resources, W.Z., T.G. and Y.O.; data curation, W.Z.; writing—original draft preparation, W.Z.; writing—revision and editing, S.-Y.J. and W.Z.; visualization, W.Z.; supervision, S.-Y.J.; project administration, S.-Y.J. and W.Z.; funding acquisition, S.-Y.J. and W.Z. All authors have read and agreed to the published version of the manuscript.

Funding

This study is funded by the National Key R&D Program of China (Nos. 2017YFC0602405 and 2016YFC0600206), the National Natural Science Foundation of China (No. 41802105), the Fundamental Research Funds for the Central Universities, China University of Geosciences (Wuhan) (Nos. CUGQY1964, CUGL190807 and CUGCJ1711), and MOST Special Fund from the State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences (No. MSFGPMR03-2).

Acknowledgments

We would like to thank editor of this special issue, David R. Lentz, and three anonymous reviewers for all the constructive feedback they provided to improve this manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Shu, L. An analysis of principal features of tectonic evolution in South China Block. Geol. Bull. China 2012, 31, 1035–1053. [Google Scholar]
  2. Hua, R.M.; Chen, P.R.; Zhang, W.L.; Yao, J.M.; Lin, J.F.; Zhang, Z.S.; Gu, S.Y. Metallogenies and their geodynamics setting related to Mesozoic granitoids in the Nanling Range. Geol. J. China Univ. 2005, 11, 291–304. (In Chinese) [Google Scholar]
  3. Mao, J.W.; Xie, G.Q.; Guo, C.L.; Yuan, S.D.; Cheng, Y.B.; Chen, Y.C. Spatial-temporal distribution of Mesozoic ore deposits in South China and their metallogenic settings. Geol. J. China Univ. 2008, 14, 510–526. (In Chinese) [Google Scholar]
  4. Qi, Y.Q.; Hu, R.Z.; Liu, S.; Coulson, I.M.; Qi, H.W.; Tian, J.J.; Zhu, J.J. Petrogenesis and geodynamic setting of Early Cretaceous mafic–ultramafic intrusions, South China: A case study from the Gan–Hang tectonic belt. Lithos 2016, 258–259, 149–162. [Google Scholar] [CrossRef]
  5. Zhou, X.M.; Li, W.X. Origin of Late Mesozoic igneous rocks in Southeastern China: Implications for lithosphere subduction and underplating of mafic magmas. Tectonophysics 2000, 326, 269–287. [Google Scholar] [CrossRef]
  6. Li, X.H.; Chung, S.L.; Zhou, H.W.; Lo, C.H.; Liu, Y.; Chen, C.H. Jurassic intraplate magmatism in southern Hunan-eastern Guangxi: 40Ar/39Ar dating, geochemistry, Sr–Nd isotopes and implications for the tectonic evolution of SE China. Geol. Soc. Lond. Spec. Publ. 2004, 226, 193–215. [Google Scholar] [CrossRef]
  7. Wang, Q.; Wyman, D.A.; Xu, J.F.; Zhao, Z.H.; Jian, P.; Xiong, X.L.; Bao, Z.W.; Li, C.F.; Bai, Z.H. Petrogenesis of Cretaceous adakitic and shoshonitic igneous rocks in the Luzong area, Anhui Province (Eastern China): Implications for geodynamics and Cu–Au mineralization. Lithos 2006, 89, 424–446. [Google Scholar] [CrossRef]
  8. Deng, Z.B.; Liu, S.W.; Zhang, L.F.; Wang, Z.Q.; Wang, W.; Yang, P.T.; Luo, P.; Guo, B.R. Geochemistry, zircon U–Pb and Lu–Hf isotopes of an Early Cretaceous intrusive suite in northeastern Jiangxi Province, South China Block: Implications for petrogenesis, crust/mantle interactions and geodynamic processes. Lithos 2014, 200–201, 334–354. [Google Scholar] [CrossRef]
  9. Wang, Y.J.; Fan, W.M.; Guo, F.; Peng, T.P.; Li, C.W. Geochemistry of Mesozoic Mafic Rocks Adjacent to the Chenzhou-Linwu fault, South China: Implications for the Lithospheric Boundary between the Yangtze and Cathaysia Blocks. Inter. Geol. Rev. 2003, 45, 263–286. [Google Scholar] [CrossRef]
  10. Gan, C.S.; Wang, Y.J.; Barry, T.L.; Zhang, Y.Z.; Qian, X. Late Jurassic high-Mg andesites in the Youjiang Basin and their significance for the southward continuation of the Jiangnan Orogen, South China. Gondwana Res. 2020, 77, 260–273. [Google Scholar] [CrossRef]
  11. Wang, G.G.; Ni, P.; Yao, J.; Wang, X.L.; Zhao, K.D.; Zhu, R.Z.; Xu, Y.F.; Pan, J.Y.; Li, L.; Zhang, Y.H. The link between subduction-modified lithosphere and the giant Dexing porphyry copper deposit, South China: Constraints from high-Mg adakitic rocks. Ore Geol. Rev. 2015, 67, 109–126. [Google Scholar] [CrossRef]
  12. Vigouroux, N.; Wallace, P.J.; Williams-Jones, G.; Kelley, K.; Kent, A.J.R.; Williams-Jones, A.E. The sources of volatile and fluid-mobile elements in the Sunda arc: A melt inclusion study from Kawah Ijen and Tambora volcanoes, Indonesia. Geochem. Geophys. Geosyst. 2012, 13, 1–22. [Google Scholar] [CrossRef] [Green Version]
  13. Mao, J.W.; Xiong, B.K.; Liu, J.; Pirajno, F.; Cheng, Y.B.; Ye, H.S.; Song, S.W.; Dai, P. Molybdenite Re/Os dating, zircon U–Pb age and geochemistry of granitoids in the Yangchuling porphyry W–Mo deposit (Jiangnan tungsten ore belt), China: Implications for petrogenesis, mineralization and geodynamic setting. Lithos 2017, 286–287, 35–52. [Google Scholar] [CrossRef]
  14. Song, S.W.; Mao, J.W.; Zhu, Y.F.; Yao, Z.Y.; Chen, G.H.; Rao, J.F.; Ouyang, Y.P. Partial-melting of fertile metasedimentary rocks controlling the ore formation in the Jiangnan porphyry-skarn tungsten belt, South China: A case study at the giant Zhuxi W-Cu skarn deposit. Lithos 2018, 304–307, 180–199. [Google Scholar] [CrossRef]
  15. Liu, X.; Fan, H.R.; Santosh, M.; Hu, F.F.; Yang, K.F.; Li, Q.L.; Yang, Y.H.; Liu, Y.S. Remelting of Neoproterozoic relict volcanic arcs in the Middle Jurassic: Implication for the formation of the Dexing porphyry copper deposit, Southeastern China. Lithos 2012, 150, 85–100. [Google Scholar] [CrossRef]
  16. Wang, X.L.; Zhou, J.C.; Griffin, W.L.; Wang, R.C.; Qiu, J.S.; O’Reilly, S.Y.; Xu, X.S.; Liu, X.M.; Zhang, G.L. Detrital zircon geochronology of precambrian basement sequences in the Jiangnan orogen: Dating the assembly of the Yangtze and Cathaysia blocks. Precambrian Res. 2007, 159, 117–131. [Google Scholar] [CrossRef]
  17. Sun, K.K.; Chen, B.; Deng, J. Ore genesis of the Zhuxi supergiant W-Cu skarn polymetallic deposit, South China: Evidence from scheelite geochemistry. Ore Geol. Rev. 2019, 107, 14–29. [Google Scholar] [CrossRef]
  18. Wang, C.B.; Rao, J.F.; Chen, J.G.; Ouyang, Y.P.; Qi, S.J.; Li, Q. Prospectivity mapping for “Zhuxi-type” copper-tungsten polymetallic deposits in the Jingdezhen region of Jiangxi Province, South China. Ore Geol. Rev. 2017, 89, 1–14. [Google Scholar] [CrossRef]
  19. Pan, X.F.; Hou, Z.Q.; Zhao, M.; Chen, G.H.; Rao, J.F.; Li, Y.; Wei, J.; Ouyang, Y.P. Geochronology and geochemistry of the granites from the Zhuxi W(Cu)ore deposit in South China: Implication for petrogenesis, geodynamical setting and mineralization. Lithos 2018, 304–307, 155–179. [Google Scholar] [CrossRef]
  20. Pan, X.F.; Hou, Z.Q.; Li, Y.; Chen, G.H.; Zhao, M.; Zhang, T.F.; Zhang, C.; Wei, J.; Kang, C. Dating the giant Zhuxi W(Cu) deposit (Taqian-Fuchun Ore Belt) in South China using molybdenite Re-Os and muscovite Ar-Ar system. Ore Geol. Rev. 2017, 86, 719–733. [Google Scholar] [CrossRef]
  21. Song, S.W.; Mao, J.W.; Xie, G.Q.; Chen, L.; Santosh, M.; Chen, G.H.; Rao, J.F.; Ouyang, Y.P. In situ LA-ICP-MS U-Pb geochronology and trace element analysis of hydrothermal titanite from the giant Zhuxi W(Cu) skarn deposit, South China. Mineral. Depos. 2019, 54, 569–590. [Google Scholar] [CrossRef]
  22. Liu, Y.S.; Hu, Z.C.; Gao, S.; Gunther, D.; Xu, J.; Gao, C.G.; Chen, H.H. In Situ analysis of major and trace elements of anhydrous minerals by LA-ICP-MS without applying an internal standard. Chem. Geol. 2008, 257, 34–43. [Google Scholar] [CrossRef]
  23. Chen, W.; Lu, J.; Jiang, S.Y.; Ying, Y.C.; Liu, Y.S. Radiogenic Pb reservoir contributes to the rare earth element (REE) enrichment in South Qinling carbonatites. Chem. Geol. 2018, 494, 80–95. [Google Scholar] [CrossRef]
  24. Jiang, Y.H.; Jiang, S.Y.; Ling, H.F.; Ni, P. Petrogenesis and tectonic implications of Late Jurassic shoshonitic lamprophyre dikes from the Liaodong Peninsula, NE China. Mineral. Petrol. 2010, 100, 127–151. [Google Scholar] [CrossRef]
  25. Xie, G.Q. Late Mesozoic and Cenozoic Mafic Dikes (bodies) from Southeastern China: Geological and geochemical characteristics and its geodynamics—A case of Jiangxi Province. Ph.D. Thesis, Institute of Geochemistry, Chinese Academy of Sciences, Guiyang, China, 2003. (In Chinese). [Google Scholar]
  26. Rock, N.M.S. The nature and origin of lamprophyres: An overview. In Alkaline Igneous Rocks; Special Publication; Fitton, J.G., Upton, B.G.J., Eds.; Geological Society of London: London, UK, 1987; Volume 30, pp. 191–226. [Google Scholar]
  27. Peccerillo, R.; Taylor, S.R. Geochemistry of Eocene calc-alkaline volcanic rocks from the Kastamonu area, northern Turkey. Contrib. Mineral. Petrol. 1976, 58, 63–81. [Google Scholar] [CrossRef]
  28. Le Maitre, R.W. Igneous Rocks: A Classification and Glossary of Terms, 2nd ed.; Cambridge University Press: Cambridge, UK, 2002; pp. 1–236. [Google Scholar]
  29. Plank, T. The Chemical Composition of Subducting Sediments. In Treatise on Geochemistry; Elsevier: Oxford, UK, 2014; pp. 607–629. [Google Scholar]
  30. Rudnick, R.L.; Fountain, D.M. Nature and composition of the continental crust: A lower crustal perspective. Rev. Geophys. 1995, 33, 267–309. [Google Scholar] [CrossRef] [Green Version]
  31. Su, Y.J. Mid-ocean ridge basalt trace element systematics: Constraints from database management, ICPMS analyses, global data compilation and petrologic modeling. Ph.D. Thesis, Columbia University, New York, NY, USA, 2002. [Google Scholar]
  32. Sun, S.S.; McDonough, W.F. Chemical and isotopic systematics of oceanic basalts: Implications for mantle compositions and processes. In Magmatism in the Ocean Basins; Special Publication; Saunders, A.D., Norry, M.J., Eds.; Geological Society of London: London, UK, 1989; Volume 42, pp. 313–345. [Google Scholar]
  33. Broderick, C.A. The origin of sulfur-rich apatites in silicic magmas. Master’s Thesis, Portland State University, Portland, OR, USA, 2008. [Google Scholar]
  34. Malarkey, J.; Pearson, D.G.; Kjarsgaard, B.A.; Davidson, J.P.; Nowell, G.M.; Ottley, C.J.; Stammer, J. From source to crust: Tracing magmatic evolution in a kimberlite and a melilitite using microsample geochemistry. Earth Planet. Sci. Lett. 2010, 299, 80–90. [Google Scholar] [CrossRef]
  35. Foley, S.F.; Jackson, S.E.; Fryer, B.J.; Greenough, J.D.; Jenner, G.A. Trace element partition coefficients for clinopyroxene and phlogopite in an alkaline lamprophyre from Newfoundland by LAM-ICP-MS. Geochim. Cosmochim. Acta 1996, 60, 629–638. [Google Scholar] [CrossRef]
  36. LaTourette, T.; Hervig, R.L.; Holloway, J.R. Trace element partitioning between amphibole, phlogopite, and basanite melt. Earth Planet. Sci. Lett. 1995, 135, 13–30. [Google Scholar] [CrossRef]
  37. Furman, T.; Graham, D. Erosion of lithospheric mantle beneath the East African rift system: Geochemical evidence from the Kivu volcanic province. Lithos 1999, 48, 237–262. [Google Scholar] [CrossRef]
  38. Duggen, S.; Hoernle, K.; Bogaard, P.; Garbe-Schonberg, D. Post-collisional transition from subduction to intraplate type magmatism in the westernmost Mediterranean: Evidence for continental-edge delamination of subcontinental lithosphere. J. Petrol. 2005, 46, 1155–1201. [Google Scholar] [CrossRef] [Green Version]
  39. McKenzie, D.P.; O’Nions, R.K. Partial melt distributions from inversion of rare earth element concentrations. J. Petrol. 1991, 32, 1021–1091. [Google Scholar] [CrossRef]
  40. Robinson, J.A.C.; Wood, B.J. The depth of the spinel to garnet transition at the peridotite solidus. Earth Planet. Sci. Lett. 1998, 164, 277–284. [Google Scholar] [CrossRef]
  41. Klemme, S.; O’Neill, H.S.C. The near-solidus transition from garnet lherzolite to spinel lherzolite. Contrib. Mineral. Petrol. 2000, 138, 237–248. [Google Scholar] [CrossRef]
  42. Thirlwall, M.F.; Smith, T.E.; Graham, A.M.; Theodorou, N.; Hollings, P.; Davidson, J.P.; Arculus, R.J. High field strength element anomalies in arc lavas: Source or process? J. Petrol. 1994, 35, 819–838. [Google Scholar] [CrossRef]
  43. Willbold, M.; Stracke, A. Formation of enriched mantle components by recycling of upper and lower continental crust. Chem. Geol. 2010, 276, 188–197. [Google Scholar] [CrossRef]
  44. Ryerson, F.J.; Watson, E.B. Rutile saturation in magmas: Implications for Ti-Nb-Ta depletion in island-arc basalts. Earth Planet. Sci. Lett. 1987, 86, 225–239. [Google Scholar] [CrossRef]
  45. Foley, S.F.; Barth, M.G.; Jenner, G.A. Rutile/melt partition coefficients for trace elements and an assessment of the influence of rutile on the trace element characteristics of subduction zone magmas. Geochim. Cosmochim. Acta 2000, 64, 933–938. [Google Scholar] [CrossRef] [Green Version]
  46. Hofmann, A.W.; Jochum, K.P.; Seufert, M.; White, W.M. Nb and Pb in oceanic basalts: New constraints on mantle evolution. Earth Planet. Sci. Lett. 1986, 79, 33–45. [Google Scholar] [CrossRef]
  47. Hofmann, A.W. Mantle geochemistry: The message from oceanic volcanism. Nature 1997, 385, 219–229. [Google Scholar] [CrossRef]
  48. Rudnick, R.L.; Gao, S. Composition of the continental crust. In Treatise on Geochemistry; Holland, H.D., Turekian, K.K., Eds.; Elsevier-Pergamon: Oxford, UK, 2003; pp. 1–64. [Google Scholar]
  49. Sims, K.W.W.; De Paolo, D.J. Inferences about mantle magma sources from incompatible element concentration ratios in oceanic basalts. Geochim. Cosmochim. Acta 1997, 61, 765–784. [Google Scholar] [CrossRef]
  50. Yang, Z.Y.; Jiang, S.Y. Diverse lamprophyres origins corresponding to lithospheric thinning: A case study in the Jiurui district of Middle-Lower Yangtze River Belt, South China Craton. Gondwana Res. 2018, 54, 62–80. [Google Scholar] [CrossRef]
  51. Münker, C.; Pfänder, J.A.; Weyer, S.; Büchl, A.; Kleine, T.; Mezger, K. Evolution of planetary cores and the Earth-Moon system from Nb/Ta systematics. Science 2003, 301, 84–87. [Google Scholar] [CrossRef]
  52. Schmidt, A.; Weyer, S.; John, T.; Brey, G.P. HFSE systematics of rutile-bearing eclogites: New insights into subduction zone processes and implications for the earth’s HFSE budget. Geochim. Cosmochim. Acta 2009, 73, 455–468. [Google Scholar] [CrossRef]
  53. König, S.; Schuth, S. Deep melting of old subducted oceanic crust recorded by superchondritic Nb/Ta in modern island arc lavas. Earth Planet. Sci. Lett. 2011, 301, 265–274. [Google Scholar] [CrossRef]
  54. Karsli, O.; Dokuz, A.; Kaliwoda, M.; Uysal, Y.; Aydin, F.; Kandemir, R.; Fehr, K.T. Petrology and mineralogy of the La Peña igneous complex, Mendoza, Argentina: An alkaline occurrence in the Miocene magmatism of the Southern Central Andes. Lithos 2014, 196–197, 181–197. [Google Scholar] [CrossRef]
  55. Pearce, J.A. Geochemical fingerprinting of oceanic basalts with applications to ophiolite classification and the search for Archean oceanic crust. Lithos 2008, 100, 14–48. [Google Scholar] [CrossRef]
  56. LaFlèche, M.R.; Camire, G.; Jenner, G.A. Geochemistry of post Acadian, Carboniferous continental intraplate basalts from the Marimes Basin, Magdalen Islands, Quebec, Canada. Chem. Geol. 1998, 148, 115–136. [Google Scholar] [CrossRef]
  57. Klimm, K.; Blundy, J.D.; Green, T.H. Trace element partitioning and accessory phase saturation during H2O-saturated melting of basalt with implications for subduction zone chemical fluxes. J. Petrol. 2008, 49, 523–553. [Google Scholar] [CrossRef] [Green Version]
  58. Hermann, J.; Rubatto, D. Accessory phase control on the trace element signature of sediment melts in subduction zones. Chem. Geol. 2009, 265, 512–526. [Google Scholar] [CrossRef]
  59. Van Hoose, A.E.V.; Streck, M.J.; Pallister, J.S.; Wälle, M. Sulfur evolution of the 1991 Pinatubo magmas based on apatite. J. Volcanol. Geotherm. Res. 2013, 257, 72–89. [Google Scholar] [CrossRef]
  60. Straub, S.; Layne, G.D. The systematics of chlorine, fluorine, and water in Izu arc front volcanic rocks: Implications for volatile recycling in subduction zones. Geochim. Cosmochim. Acta 2003, 67, 4179–4203. [Google Scholar] [CrossRef]
  61. O’Reilly, S.Y.; Griffin, W.L. Apatite in the mantle: Implications for metasomatic processes and high heat production in Phanerozoic mantle. Lithos 2000, 53, 217–232. [Google Scholar] [CrossRef]
  62. Lassiter, J.C.; Hauri, E.H.; Nikogosian, I.K.; Barsczus, H.G. Chlorine-potassium variations in melt inclusions from Raivavae and Rapa, Austral Islands: Constraints on chlorine recycling in the mantle and evidence for brine-induced melting of oceanic crust. Earth Planet. Sci. Lett. 2002, 202, 525–540. [Google Scholar] [CrossRef]
  63. Stroncik, N.A.; Haase, K.M. Chlorine in oceanic intraplate basalts: Constraints on mantle sources and recycling processes. Geology 2004, 32, 945–948. [Google Scholar] [CrossRef]
  64. Mathez, E.A.; Webster, J.D. Partitioning behavior of chlorine and fluorine in the system apatite-silicate melt-fluid. Geochim. Cosmochim. Acta 2005, 69, 1275–1286. [Google Scholar] [CrossRef]
  65. Hedenqulst, J.W.; Lowenstern, J.B. The role of magmas in the formation of hydrothermal ore deposits. Nature 1994, 18, 519–527. [Google Scholar] [CrossRef]
  66. Boyce, J.W.; Hervig, R.L. Apatite as a monitor of late-stage magmatic processes at Volcán Irazú, Costa Rica. Contrib. Mineral. Petrol. 2009, 157, 135–145. [Google Scholar] [CrossRef]
  67. Baker, L.L.; Rutherford, M.J. Sulfur diffusion in rhyolite melts. Contrib. Mineral. Petrol. 1996, 123, 335–344. [Google Scholar] [CrossRef]
  68. Jugo, P.J.; Luth, R.W.; Richards, J.P. An experimental study of the sulfur content in basaltic melts saturated with immiscible sulfide or sulfate liquids at 1300 °C and 1.0 GPa. J. Petrol. 2005, 46, 783–798. [Google Scholar] [CrossRef] [Green Version]
  69. Alt, J.C.; Burdett, J.W. Sulfur in Pacific deep-sea sediments (leg 129) and implications for cycling of sediment in subduction zones. Proc. Ocean Drill. Program Sci. Results 1982, 129, 283–294. [Google Scholar]
  70. Zhou, X.M.; Sun, T.; Shen, W.Z.; Shu, L.S.; Niu, Y.L. Petrogenesis of Mesozoic granitoids and volcanic rocks in South China: A response to tectonic evolution. Episodes 2006, 29, 26–33. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  71. Xie, G.Q.; Hu, R.Z.; Zhao, J.H.; Jiang, G.H. Mantle plume and the relationship between it and Mesozoic large-scale metallogenesis in southeastern China: A preliminary discussion. Geotecton. Metallog. 2001, 25, 179–186. (In Chinese) [Google Scholar]
  72. Lu, L.; Liang, T.; Ren, W.Q.; Liu, S.B.; Zhao, Z.; Chen, Z.H.; Liu, Z.Q. Zircon U-Pb dating of the lamprophyre in Taoxikeng tungsten deposit of Chongyi, Southern Jiangxi Province and its geological significance. Earth Sci. Front. 2017, 24, 93–108. [Google Scholar]
  73. Jiang, Y.H.; Jiang, S.Y.; Zhao, K.D.; Ling, H.F. Petrogenesis of Late Jurassic Qianlishan granites and mafic dykes, Southeast China: Implications for a back-arc extension setting. Geol. Mag. 2006, 143, 457–474. [Google Scholar] [CrossRef] [Green Version]
  74. Jiang, Y.H.; Wang, G.C.; Liu, Z.; Ni, C.Y.; Qing, L.; Zhang, Q. Repeated slab advance—Retreat of the Palaeo-Pacific plate underneath SE China. Inter. Geol. Rev. 2015, 57, 472–491. [Google Scholar] [CrossRef]
  75. Yang, S.Y.; Jiang, S.Y.; Zhao, K.D.; Jiang, Y.H.; Ling, H.F.; Luo, L. Geochronology, geochemistry and tectonic significance of two Early Cretaceous A-type granites in the Gan-Hang Belt, Southeast China. Lithos 2012, 150, 155–170. [Google Scholar] [CrossRef]
  76. Zhao, J.H.; Asimow, P.D. Neoproterozoic boninite-series rocks in South China: A depleted mantle source modified by sediment-derived melt. Chem. Geol. 2014, 388, 98–111. [Google Scholar] [CrossRef] [Green Version]
  77. Zhang, Y.Z.; Wang, Y.J.; Fan, W.M.; Zhang, A.M.; Ma, L.Y. Geochronological and geochemical constraints on the metasomatised source for the Neoproterozoic (~825 Ma) high-mg volcanic rocks from the Cangshuipu area (Hunan Province) along the Jiangnan domain and their tectonic implications. Precambrian Res. 2012, 220–221, 139–157. [Google Scholar] [CrossRef]
  78. Zhao, J.H.; Zhou, M.F. Neoproterozoic high-Mg basalts formed by melting of ambient mantle in South China. Precambrian Res. 2013, 233, 193–205. [Google Scholar] [CrossRef]
  79. Rasmussen, K.L.; Lentz, D.R.; Falck, H.; Pattison, D.R. Felsic magmatic phases and the role of late-stage aplitic dykes in the formation of the world-class Cantung Tungsten skarn deposit, Northwest Territories, Canada. Ore Geol. Rev. 2011, 41, 75–111. [Google Scholar] [CrossRef]
  80. Štemprok, M.; DolejŠ, D.; Holub, F.V. Late Variscan calc-alkaline lamprophyres in the Krupka ore district, Eastern Krušné hory/Erzgebirge: Their relationship to Sn–W mineralization. J. Geosci. 2014, 59, 41–68. [Google Scholar] [CrossRef] [Green Version]
  81. Pan, X.F.; Hou, Z.Q.; Zhao, M.; Li, Y.; Ouyang, Y.P.; Wei, J.; Yang, Y.S. Fluid inclusion and stable isotope constraints on the genesis of the world-class Zhuxi W(Cu) skarn deposit in South China. J. Asian Earth Sci. 2020, 190. (in press). [Google Scholar] [CrossRef]
  82. Frost, D.J.; McCammon, C.A. The Redox State of Earth’s Mantle. Ann. Rev. Earth Planet. Sci. 2008, 36, 389–420. [Google Scholar] [CrossRef]
  83. Soloviev, S.G.; Kryazhev, S.G.; Dvurechenskaya, S.S. Genesis of the Maikhura tungsten-tin skarn deposit, Tajik Tien Shan: Insights from petrology, mineralogy, and fluid inclusion study. Ore Geol. Rev. 2019, 104, 561–588. [Google Scholar] [CrossRef]
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Figure 1. Regional geological map of the Jiangnan porphyry–skarn W belt (JNB) (modified from [13]).
Figure 1. Regional geological map of the Jiangnan porphyry–skarn W belt (JNB) (modified from [13]).
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Figure 2. Geological map of the Zhuxi W–Cu deposit (after [14]).
Figure 2. Geological map of the Zhuxi W–Cu deposit (after [14]).
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Figure 3. Geological cross-section through the Zhuxi deposit along exploration line 42 (after [14]).
Figure 3. Geological cross-section through the Zhuxi deposit along exploration line 42 (after [14]).
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Figure 4. (a) Drill cores showing the lamprophyres intruded into the Triassic sedimentary rocks at Zhuxi; (b) a hand specimen of fresh lamprophyre from Zhuxi; (c) porphyritic texture with biotite and amphibole phenocrysts in the Zhuxi lamprophyres (cross-polarized light); (df) SEM pictures show the occurrence of amphibole, plagioclase, apatite, chlorite, and calcite in the Zhuxi lamprophyre samples. Amp—amphibole; Ap—apatite; Chl—chlorite; Cal—calcite; Pl—plagioclase.
Figure 4. (a) Drill cores showing the lamprophyres intruded into the Triassic sedimentary rocks at Zhuxi; (b) a hand specimen of fresh lamprophyre from Zhuxi; (c) porphyritic texture with biotite and amphibole phenocrysts in the Zhuxi lamprophyres (cross-polarized light); (df) SEM pictures show the occurrence of amphibole, plagioclase, apatite, chlorite, and calcite in the Zhuxi lamprophyre samples. Amp—amphibole; Ap—apatite; Chl—chlorite; Cal—calcite; Pl—plagioclase.
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Figure 5. Zircon U–Pb concordia and weighted mean ages for the Zhuxi lamprophyres (see Table 1).
Figure 5. Zircon U–Pb concordia and weighted mean ages for the Zhuxi lamprophyres (see Table 1).
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Figure 6. Major element compositions (wt%) of the Zhuxi lamprophyres (see Table 2). The K2O vs. SiO2 diagram is after [26,27,28]. Data of Wushan lamprophyres and Quzhou and Longyou mafic intrusions are from [4,25].
Figure 6. Major element compositions (wt%) of the Zhuxi lamprophyres (see Table 2). The K2O vs. SiO2 diagram is after [26,27,28]. Data of Wushan lamprophyres and Quzhou and Longyou mafic intrusions are from [4,25].
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Figure 7. (a) Chondrite-normalized REE patterns and (b) primitive mantle-normalized spider diagrams [32] for the Zhuxi lamprophyres (see Table 2). Compositions of ocean island basalt (OIB) and global subducting sediment II (GLOSS-II) are from [30]. Wushan, Quzhou, and Longyou data are from [4,25].
Figure 7. (a) Chondrite-normalized REE patterns and (b) primitive mantle-normalized spider diagrams [32] for the Zhuxi lamprophyres (see Table 2). Compositions of ocean island basalt (OIB) and global subducting sediment II (GLOSS-II) are from [30]. Wushan, Quzhou, and Longyou data are from [4,25].
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Minerals 10 00642 g008 550
Figure 8. (a) Chondrite-normalized REE patterns and (b) primitive mantle-normalized spider diagrams [32] for the apatites in Zhuxi lamprophyres (see Table 3).
Figure 8. (a) Chondrite-normalized REE patterns and (b) primitive mantle-normalized spider diagrams [32] for the apatites in Zhuxi lamprophyres (see Table 3).
Minerals 10 00642 g008
Minerals 10 00642 g009 550
Figure 9. Sr content and Sr isotopic compositions of apatites in the Zhuxi lamprophyres (see Table 3).
Figure 9. Sr content and Sr isotopic compositions of apatites in the Zhuxi lamprophyres (see Table 3).
Minerals 10 00642 g009
Minerals 10 00642 g010 550
Figure 10. (a) Rb/Sr vs. Ba/Rb diagram (see e.g., [37]); (b) plot of K/Yb/1000 vs. Dy/Yb for the Zhuxi lamprophyres (see Table 2), Wushan lamporphyres [25], and Quzhou and Longyou ultramafic intrusions [4]. Various lherzolite melting curves are from [38].
Figure 10. (a) Rb/Sr vs. Ba/Rb diagram (see e.g., [37]); (b) plot of K/Yb/1000 vs. Dy/Yb for the Zhuxi lamprophyres (see Table 2), Wushan lamporphyres [25], and Quzhou and Longyou ultramafic intrusions [4]. Various lherzolite melting curves are from [38].
Minerals 10 00642 g010
Minerals 10 00642 g011 550
Figure 11. (a) La/Yb vs. Nb/La diagram ([54]); (b) Th/Yb vs. Nb/Yb diagram ([55]); (c) Nb/U vs. Nb diagram (data for each source member is from [46,49]); (d) (Ta/La)N vs. (Hf/Sm)N diagram ([56]), for the Zhuxi lamprophyres (see Table 2).
Figure 11. (a) La/Yb vs. Nb/La diagram ([54]); (b) Th/Yb vs. Nb/Yb diagram ([55]); (c) Nb/U vs. Nb diagram (data for each source member is from [46,49]); (d) (Ta/La)N vs. (Hf/Sm)N diagram ([56]), for the Zhuxi lamprophyres (see Table 2).
Minerals 10 00642 g011
Table
Table 1. LA–ICP–MS zircon U–Pb dating for the Zhuxi lamprophyres.
Table 1. LA–ICP–MS zircon U–Pb dating for the Zhuxi lamprophyres.
Analysis SpotThU207Pb/235U206Pb/238Urho207Pb/235U206Pb/238U
ppmppmRatioRatioAge (Ma)Age (Ma)
GC4-11105420.16580.00590.0242 0.00030.3298 1565.2 1541.8
GC4-284.911380.16690.00820.0243 0.00040.3615 1577.2 1552.7
GC4-328.64600.16550.00760.0243 0.00040.3185 1566.6 1552.2
GC4-418.74500.18110.00810.0247 0.00030.2745 1697.0 1581.9
GC4-568.75380.16980.00650.0248 0.00030.2892 1595.6 1581.7
GC4-630.14180.16280.00860.0249 0.00030.2323 1537.5 1591.9
GC4-716.512600.17270.00490.0249 0.00020.3450 1624.3 1591.5
GC4-81565560.17780.00670.0250 0.00030.3155 1665.8 1591.9
GC4-913214590.16800.00470.0252 0.00020.3476 1584.1 1601.5
GC4-1030.33740.16200.00660.0255 0.00040.3389 1525.8 1622.2
GC4-1141.48480.18840.00700.0255 0.00040.4335 1756.0 1622.6
Table
Table 2. Major element (in wt%) and trace element (in ppm) compositions of the Zhuxi lamprophyres.
Table 2. Major element (in wt%) and trace element (in ppm) compositions of the Zhuxi lamprophyres.
SampleSiO2TiO2Al2O3TFe2O3 *MnOMgOCaONa2OK2OP2O5LOITotalLiBeScCrVCoNiCsPbUSrRbBaTh
ZX10959.040.9514.105.930.083.754.842.014.060.494.7399.98174 3.61 16.62 90.3 120 18.23 57.6 36.9 12.8 2.34 587 251 1550 22.8
ZX11059.631.0014.295.930.103.953.612.144.960.453.0199.07174 3.61 16.33 92.1 118 17.67 58.5 36.1 12.8 2.18 583 249 1577 22.1
ZX11160.271.0114.526.110.104.193.862.183.480.463.5399.71173 2.86 16.70 101 124 19.54 63.7 28.3 13.0 2.11 792 166 1562 18.9
ZX11260.761.0114.486.410.093.923.722.482.520.443.7899.61157 2.97 17.35 105 126 20.09 65.1 32.2 12.9 2.06 767 151 1010 19.0
ZX11358.980.9313.955.920.093.865.063.193.900.482.9899.3469.97 3.69 16.83 102 126 18.34 61.3 15.5 16.7 2.37 760 180 1113 21.9
SampleTaNbZrHfYLaCePrNdSmEuGdTbDyHoErTmYbLuCuZnGaMoSnWBi
ZX1090.68 11.34 296 7.9825.40 90.62 184.2 20.11 72.08 11.74 3.41 11.77 1.12 5.00 0.97 2.76 0.34 2.21 0.33 87.5 58.1 23.9 1.05 5.01 1.50 0.70
ZX1100.67 11.23 298 7.9125.31 89.36 181.9 19.93 73.44 11.59 3.40 11.73 1.11 4.99 0.97 2.73 0.34 2.21 0.32 90.3 60.9 23.8 1.67 5.05 1.45 0.69
ZX1110.73 11.53 294 7.9026.59 88.90 185.8 20.32 73.58 11.71 3.27 11.92 1.14 5.19 1.03 2.91 0.38 2.46 0.36 28.1 62.8 24.8 0.56 2.65 1.65 0.15
ZX1120.73 12.05 297 7.9627.19 88.16 179.5 19.79 73.27 11.50 2.94 11.58 1.14 5.31 1.05 2.98 0.39 2.51 0.37 35.5 57.3 25.2 0.43 6.50 1.69 0.19
ZX1130.66 11.50 299 7.8525.27 89.70 182.8 19.86 73.87 11.43 2.99 11.51 1.10 4.84 0.95 2.70 0.34 2.20 0.32 144 62.6 24.6 1.77 4.06 1.67 0.48
* TFe2O3 = Fe2O3 + 1.111 × FeO.
Table
Table 3. Major elements (in wt%) and trace elements (in ppm), and Sr isotope compositions of apatites from the Zhuxi lamprophyres.
Table 3. Major elements (in wt%) and trace elements (in ppm), and Sr isotope compositions of apatites from the Zhuxi lamprophyres.
SampleGC-4-1GC-4-2 GC-4-3 GC-4-4 GC-4-5 GC-4-6 GC-4-7 GC-4-8 GC-4-9 GC-4-10
MgO0.260.330.160.120.440.180.230.180.310.25
SiO20.190.180.240.190.180.160.200.180.180.18
MnO0.050.030.080.080.000.080.070.040.040.06
FeOt0.320.310.290.180.440.260.390.310.310.36
CaO53.8253.9653.5454.2253.7454.2153.6553.9254.1654.01
TiO20.000.000.000.010.000.000.000.020.000.00
Na2O0.210.140.270.140.230.250.290.230.190.26
K2O0.000.000.000.000.010.000.000.000.000.00
Al2O30.000.000.020.020.030.040.020.010.010.02
P2O540.2640.4039.5140.3539.6940.3440.2639.8240.0440.72
SrO0.220.220.290.370.320.230.240.250.230.20
F2.111.852.312.151.962.302.061.922.162.03
Cl0.400.380.420.370.570.410.390.570.380.53
SO3 1.010.911.010.861.090.931.120.890.791.08
Total 97.8897.8497.0798.0597.7498.3297.9797.4097.7898.71
Li1.44 1.10 1.48 1.33 1.28 0.91 1.53 1.48 1.22 1.63
Be0.00 0.08 0.29 0.00 0.08 0.00 0.00 0.00 0.05 0.00
B2.52 2.18 3.58 3.04 2.20 3.32 3.85 1.06 1.96 1.75
Sc0.93 1.51 1.03 0.95 1.03 0.96 0.95 1.45 1.33 1.52
V25.28 24.23 25.51 28.03 21.79 18.77 18.93 22.08 27.91 18.65
Cr0.85 0.09 0.00 0.00 0.00 0.41 0.00 0.00 0.33 0.00
Co0.61 0.75 0.43 0.19 0.41 0.78 0.72 0.16 0.66 0.52
Ni0.00 0.17 0.00 0.00 0.03 0.00 0.00 0.30 0.41 0.57
Cu0.39 0.09 0.08 0.45 0.08 0.40 0.13 0.08 0.22 0.55
Zn0.75 1.22 1.58 0.82 1.33 1.59 1.56 2.05 1.84 1.92
Ga14.16 16.40 22.13 18.73 16.73 13.32 15.85 18.94 14.32 12.99
Ge20.62 26.14 35.22 31.09 25.63 21.51 23.80 25.67 24.32 18.77
As6.10 6.58 7.48 6.54 7.08 5.35 5.35 8.44 7.16 5.08
Rb0.04 0.06 0.00 0.09 0.00 0.00 0.03 0.09 0.09 0.04
Sr5502 5890 5027 6080 5763 5303 5269 5050 5544 4763
Y146 162 222 175 160 125 144 193 144 144
Zr7.50 8.28 12.92 7.64 9.22 8.28 8.39 11.93 7.74 10.04
Nb0.01 0.00 0.06 0.02 0.02 0.02 0.05 0.07 0.03 0.06
Mo0.00 0.00 0.04 0.01 0.07 0.00 0.02 0.03 0.00 0.15
Cd0.20 0.18 0.00 0.20 0.33 0.13 0.31 0.15 0.18 0.30
In0.00 0.02 0.00 0.00 0.01 0.00 0.00 0.01 0.02 0.01
Sn0.11 0.31 0.13 0.20 0.33 0.41 0.41 0.11 0.34 0.25
Sb0.03 0.01 0.00 0.01 0.01 0.04 0.04 0.00 0.04 0.08
Cs0.00 0.02 0.00 0.02 0.01 0.02 0.00 0.00 0.04 0.02
Ba49.22 55.01 36.45 43.75 45.31 53.17 41.34 33.78 50.79 40.05
La1413 1581 2107 1725 1648 1281 1455 1769 1437 1281
Ce3118 3483 4746 3869 3617 2824 3290 4128 3185 2902
Pr408 460 617 507 474 371 437 544 420 385
Nd1769 1989 2649 2188 2053 1612 1894 2332 1806 1667
Sm236 266 363 289 275 216 257 324 242 230
Eu49.79 56.62 73.56 60.12 57.99 45.59 52.94 65.50 50.06 47.27
Gd124.9 140.2 190.7 149.9 143.6 112.8 137.0 167.5 125.0 121.5
Tb10.14 11.65 16.01 12.38 11.54 9.19 11.10 13.95 10.51 10.27
Dy39.43 44.18 61.63 47.46 44.29 33.97 40.94 53.90 39.22 38.84
Ho5.87 6.39 9.01 6.93 6.39 5.10 5.78 7.75 5.75 5.82
Er11.44 12.82 17.69 13.58 12.86 9.75 11.22 15.68 11.28 11.38
Tm1.10 1.27 1.82 1.43 1.24 1.01 1.14 1.55 1.17 1.22
Yb6.49 6.88 9.60 7.43 7.15 5.25 6.03 8.30 6.35 6.43
Lu0.80 0.90 1.24 0.96 0.79 0.63 0.74 1.02 0.72 0.73
Hf0.08 0.08 0.11 0.08 0.12 0.04 0.04 0.14 0.06 0.09
Ta0.01 0.00 0.01 0.01 0.00 0.00 0.00 0.01 0.01 0.01
W0.01 0.04 0.04 0.07 0.01 0.10 0.00 0.06 0.02 0.00
Bi0.08 0.10 0.07 0.11 0.08 0.07 0.09 0.07 0.08 0.08
Pb12.18 13.14 13.39 14.94 13.54 15.24 13.85 13.41 11.54 12.32
Th38.67 47.53 78.85 48.94 45.20 34.34 45.60 68.03 44.94 43.01
U3.37 3.67 5.64 4.05 3.38 2.84 3.77 5.01 3.47 3.34
87Sr/86Sr0.70775 0.70782 0.70774 0.70785 0.70774 0.70780 0.70768 0.70765 0.70757 0.70770
error0.00012 0.00008 0.00009 0.00007 0.00009 0.00008 0.00010 0.00010 0.00011 0.00005

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Zhang, W.; Jiang, S.-Y.; Gao, T.; Ouyang, Y.; Zhang, D. Constraints on the Petrogenesis and Metallogenic Setting of Lamprophyres in the World-Class Zhuxi W–Cu Skarn Deposit, South China. Minerals 2020, 10, 642. https://doi.org/10.3390/min10070642

AMA Style

Zhang W, Jiang S-Y, Gao T, Ouyang Y, Zhang D. Constraints on the Petrogenesis and Metallogenic Setting of Lamprophyres in the World-Class Zhuxi W–Cu Skarn Deposit, South China. Minerals. 2020; 10(7):642. https://doi.org/10.3390/min10070642

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Zhang, Wei, Shao-Yong Jiang, Tianshan Gao, Yongpeng Ouyang, and Di Zhang. 2020. "Constraints on the Petrogenesis and Metallogenic Setting of Lamprophyres in the World-Class Zhuxi W–Cu Skarn Deposit, South China" Minerals 10, no. 7: 642. https://doi.org/10.3390/min10070642

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