4.a. In situ zircon U–Pb isotope and trace-element analysis

The gabbro sample (QG-1) was selected for zircon U–Pb dating, and was collected from the exploration drillhole (ZK18-1, 145 m) of the QMC. Zircon grains were separated from the sample by conventional magnetic and density techniques at the laboratory of the Langfang Regional Geological Survey Institute in Hebei Province, China. Then, the prepared zircon grains were handpicked, embedded in epoxy resin and polished to expose the grain centres. Zircons that were free of visible inclusions and fractures were selected for cathodoluminescence (CL) imaging in the electron microprobe laboratory at the State Key Laboratory of Geological Processes and Mineral Resources (GPMR), China University of Geosciences (CUG), Wuhan. Measurements of U, Th and Pb isotopes and trace elements in the zircons were performed synchronously by using an LA-ICP-MS at GPMR. Laser sampling was conducted by using a GeoLas 2005 with a beam diameter of 32 μm, and an Agilent 7500a ICP-MS instrument was used to acquire ion-signal intensities. Helium was used as a carrier gas, while argon was used as a makeup gas. The two gases were mixed before entering the ICP. We analysed the standards 91500 and GJ-1 for U–Pb dating and NIST 610 as an external standard for trace-element analyses. Each analysis incorporated a background acquisition of 20 s followed by 60 s of data acquisition from the sample. The detailed work conditions for the laser ablation system and the ICP-MS instrument were described by Liu et al. (Reference Liu, Gao, Hu, Gao, Zong and Wang2010). The software ICPMSDataCal was used for the offline selection and integration of background and analytical signals, and time-drift correction and quantitative calibration were applied for the trace-element analyses and U–Pb dating (Liu et al. Reference Liu, Gao, Hu, Gao, Zong and Wang2010). Concordia diagrams and weighted mean calculations were conducted by using Isoplot version 3.75 (Ludwig, Reference Ludwig2012).

4.b. In situ apatite U–Pb isotope analysis

Apatite grains chosen for radiometric dating were collected from the disseminated phosphate ore sample QG-2-1. The sample analysed in this study was cast on polished sections of the microprobe slice. Before analysis, apatite grains were imaged by CL of a CL8200 MK5 (England) instrument at GPMR. U–Pb geochronology was conducted on the LA-ICP-MS instrument at GPMR. Laser ablation was accomplished using a 193 nm ArF excimer laser (RESOlution-S155), and the ablation protocol employed a spot diameter of 50 μm at 10 Hz repetition rate for 40 s. Helium gas was used as a carrier gas to transport the ablated sample to a Thermo iCAP Qc ICP-MS. During each analysis, the signals of ²⁰²Hg, ²⁰⁴(Pb + Hg), ²⁰⁶Pb, ²⁰⁷Pb, ²⁰⁸Pb, ²³²Th and ²³⁸U were collected. The Madagascar apatite (Thomson et al. Reference Thomson, Gehrel, Ruiz and Buchwaldt2012) was used as the external standard to monitor instrumental drift and laser induced elemental fractionation via a ‘standard-sample-standard bracketing’ technique. Apatite is an accessory U-bearing mineral that contains a significant amount of common Pb (Chew et al. Reference Chew, Petrus and Kamber2014). The common Pb correction method adopted in this study was similar to that described in Chen & Simonetti (Reference Chen and Simonetti2013). The common Pb isotopic composition was determined by plotting the uncorrected data on a Tera-Wasserburg diagram. Then it was used to apply a common lead correction to the measured ²⁰⁶Pb/²³⁸U ratios. The Tera-Wasserburg diagram and weighted mean ²⁰⁶Pb–²³⁸U ages reported here were determined with Isoplot software.

4.c. Electron microprobe major-element measurement

In this study, we chose 13 rock and ore samples from the QMC to analyse the major elements of olivine, pyroxene, feldspar, apatite and Fe–Ti oxides in the thin-sections. Major-element contents of minerals (e.g. olivine, pyroxene, apatite and magnetite) were determined by a JEOL JXA-8230 electron microprobe at the Wuhan Sample Solution Analytical Technology Co., Ltd, Hubei, China. The analyses were performed with the following analytical conditions: an electron beam of 3–5 μm diameter with an accelerating voltage of 20 kV and a probe current of 10 nA. The analyses were refined using the ZAF online correction program.

4.d. Whole-rock major- and trace-element analysis

Five carbonatite and/or ore samples (QG-4-1 to QG-4-5), two clinopyroxenite samples (QG-3-1 to QG-3-2) and one phlogopitelite sample (QG-5-1) selected from the exposed QMC and two gabbro samples (QG-1-1 to QG-1-2, the most evolved rock type within the QMC) selected from the drillhole (ZK18-1) of the QMC were analysed for their major and trace elements. Samples chosen for whole-rock geochemical analysis were trimmed to remove the weathered surfaces, before being crushed and powdered to 200 mesh. Major elements were analysed in a PANalytical Axios X-ray fluorescence spectrometer (XRF) at ALS Chemex (Guangzhou) Co. Ltd. Prior to analysis, a calcined or ignited sample (0.9 g) was added to 9 g of lithium borate flux (50–50 % Li₂B₄O₇–LiBO₂), mixed well and fused in an auto-fluxer at between 1050 and 1100 °C. A flat molten glass disc was prepared from the resulting melt; this disc was then analysed via XRF spectrometry. The precision of the XRF analyses at ALS Chemex is better than 5 %.

Trace-element concentrations were determined in an Elan 9000 at the same lab. A prepared sample (0.2 g) was added to lithium metaborate flux (0.9 g), mixed well and fused in a furnace at 1000 °C. The resulting melt was then cooled and dissolved in 100 mL of 4 % HNO₃/2 % HCl₃ solution. This solution was then analysed via ICP-MS. The precision of the ICP-MS analyses at ALS Chemex is better than 10 % for all elements. Data for whole-rock chemistry are reported as weight per cent (wt %), while trace-element and rare earth element (REE) values are reported in parts per million (ppm).

4.e. Whole-rock Sr–Nd isotope analysis

One carbonatite (ore) sample (QG-4-5), one clinopyroxenite sample (QG-3-3) and two gabbro samples (QG-1-1 to QG-1-2) were analysed for their Sr and Nd isotopes, and the ϵ_Nd(t) and (⁸⁷Sr/⁸⁶Sr)_i values were calculated at 811 Ma. Sr and Nd isotopic analyses were performed on a Micromass Isoprobe multi-collector (MC)-ICP-MS at the State Key Laboratory of Isotope Geochemistry (SKLIG), Guangzhou Institute of Geochemistry (GIG), Chinese Academy of Sciences (CAS), using analytical procedures described by Li et al. (Reference Li, Li, Wingate, Chung, Liu, Lin and Li2006). Sr was separated using cation columns, and Nd fractions were further separated by HDEHP-coated Kef columns. Measured ⁸⁷Sr/⁸⁶Sr and ¹⁴³Nd/¹⁴⁴Nd ratios were normalized to ⁸⁶Sr/⁸⁸Sr = 0.1194 and ¹⁴⁶Nd/¹⁴⁴Nd = 0.7219, respectively. The reported ⁸⁷Sr/⁸⁶Sr and ¹⁴³Nd/¹⁴⁴Nd ratios were adjusted to the NBS987 standard ⁸⁷Sr/⁸⁶Sr = 0.710262 ± 10 (2σ) and the Shin Etsu JNdi-1 standard ¹⁴³Nd/¹⁴⁴Nd = 0.512101 ± 4 (2σ).

4.f. In situ zircon Hf isotope analysis

In situ Lu–Hf isotopes analyses were conducted on dated zircon grains in a gabbro sample (QG-1) with identical sampling spots to the U–Pb analyses or within the same oscillatory zones. A Neptune Plus MC-ICP-MS (Thermo Fisher Scientific, Germany) equipped with a GeoLas 2005 excimer ArF laser ablation system (Lambda Physik, Göttingen, Germany) was used at GPMR. The sampling-spot size was 44 µm, and the energy density was 15–20 J cm⁻² during the analyses. The standards 91500 and GJ-1 were simultaneously analysed (Hu et al. Reference Hu, Liu, Gao, Liu, Zhang, Tong, Lin, Zong, Li, Chen, Zhou and Yang2012). The obtained Hf isotope compositions were 0.282315 ± 0.000014 (1σ) for 91500 and 0.282019 ± 0.000013 (1σ) for GJ-1. The offline selection and integration of analytical signals and mass-bias calibrations were conducted using ICPMSDataCal (Liu et al. Reference Liu, Hu, Gao, Günther, Xu, Gao and Chen2008).

4.g. In situ trace-element analyses of apatite

In this study, we chose three samples, QG-2-1, QG-2-2 and QG-3-4, to analyse the trace elements of apatite in the thin-sections. Trace-element analysis of apatite was conducted by LA-ICP-MS at the Wuhan Sample Solution Analytical Technology Co., Ltd, Wuhan, China. The samples analysed in this study were cast on polished sections of the microprobe slice. Before analysis, apatite grains were imaged by scanning electron microscope. Detailed operating conditions for the laser ablation system and the ICP-MS instrument and data reduction are the same as the description by Zong et al. (Reference Zong, Klemd, Yuan, He, Guo, Shi, Liu, Hu and Zhang2017). Laser sampling was performed using a GeoLasPro laser ablation system that consists of a COMPexPro 102 ArF excimer laser (wavelength of 193 nm and maximum energy of 200 mJ) and a MicroLas optical system. An Agilent 7700e ICP-MS instrument was used to acquire ion-signal intensities. Helium was applied as a carrier gas. Argon was used as the makeup gas and mixed with the carrier gas via a T-connector before entering the ICP. A ‘wire’ signal-smoothing device is included in this laser ablation system (Hu et al. Reference Hu, Zhang, Liu, Gao, Li, Zong, Chen and Hu2015). The spot size and frequency of the laser were set to 44 µm and 5 Hz, respectively, in this study. Trace-element compositions of minerals were calibrated against various reference materials (BHVO-2G, BCR-2G and BIR-1G) without using an internal standard (Liu et al. Reference Liu, Hu, Gao, Günther, Xu, Gao and Chen2008). Each analysis incorporated a background acquisition of ∼20–30 s followed by 50 s of data acquisition from the sample. An Excel-based software ICPMSDataCal was used to perform offline selection and integration of background and analysed signals, time-drift correction and quantitative calibration for trace-element analysis (Liu et al. Reference Liu, Hu, Gao, Günther, Xu, Gao and Chen2008).

4.h. In situ Sr–Nd–S isotope analyses of minerals

In this study, we also chose three samples, QG-2-1, QG-2-2 and QG-3-4, to analyse the Sr–Nd isotopes of apatite in the thin-sections. In situ Sr isotope ratios of apatite were measured by a Neptune Plus MC-ICP-MS (Thermo Fisher Scientific, Bremen, Germany) in combination with a GeoLasHD excimer ArF laser ablation system (Coherent, Göttingen, Germany) at the Wuhan Sample Solution Analytical Technology Co., Ltd, Hubei, China. In the laser ablation system, helium was used as the carrier gas for the ablation cell. For a single laser spot ablation, the spot size and frequency of the laser were set to 90 µm and 8 Hz, and the laser fluence was kept constant at ∼10 J cm⁻² in this study. A new signal-smoothing device (Hu et al. Reference Hu, Zhang, Liu, Gao, Li, Zong, Chen and Hu2015) was used downstream from the sample cell to eliminate the short-term variation of the signal. All data reduction for the MC-ICP-MS analysis of Sr–Nd isotope ratios was conducted using Iso-Compass software (Zhang et al. Reference Zhang, Hu and Liu2020). The interference correction strategy was the same as the one reported by Tong et al. (Reference Tong, Liu, Hu, Chen, Zhou, Hu, Xu, Deng, Chen, Yang and Gao2016) and Zhang et al. (Reference Zhang, Hu, Liu, Wu, Deng, Guo and Zhao2018). Following the interference corrections, mass fractionation of Sr isotopes was corrected by assuming ⁸⁸Sr/⁸⁶Sr = 8.375209 (Tong et al. Reference Tong, Liu, Hu, Chen, Zhou, Hu, Xu, Deng, Chen, Yang and Gao2016; Zhang et al. Reference Zhang, Hu, Liu, Wu, Deng, Guo and Zhao2018) and applying the exponential law. Two natural apatites, Durango and MAD, were used as the unknown samples for in situ Sr isotope analysis of the apatites. The chemical and Sr isotopic compositions of Durango and MAD have been reported by Yang et al. (Reference Yang, Wu, Yang, Chew, Xie, Chu, Zhang and Huang2014).

In situ Nd isotope analysis was performed on a Neptune Plus MC-ICP-MS (Thermo Fisher Scientific, Bremen, Germany) equipped with a GeoLasHD excimer ArF laser ablation system (Coherent, Göttingen, Germany) at the Wuhan Sample Solution Analytical Technology Co., Ltd, Hubei, China. In the laser ablation system, helium was used as the carrier gas within the ablation cell and was merged with argon (makeup gas) after the ablation cell. For a single laser spot ablation, the spot size and frequency of the laser were set to 90 µm and 8 Hz, and the laser fluence was kept constant at ∼8 J cm⁻² in this study. A new signal-smoothing device was used downstream from the sample cell to efficiently eliminate the short-term variation of the signal and remove the mercury from the background and sample aerosol particles (Hu et al. Reference Hu, Zhang, Liu, Gao, Li, Zong, Chen and Hu2015). The Neptune Plus was equipped with nine Faraday cups fitted with 10¹¹ Ω resistors. Isotopes ¹⁴²Nd, ¹⁴³Nd, ¹⁴⁴Nd, ¹⁴⁵Nd, ¹⁴⁶Nd, ¹⁴⁷Sm, ¹⁴⁸Nd and ¹⁴⁹Sm were collected in Faraday cups using static mode. The mass discrimination factor for ¹⁴³Nd/¹⁴⁴Nd was determined using ¹⁴⁶Nd/¹⁴⁴Nd (0.7219) with the exponential law. The ¹⁴⁹Sm signal was used to correct the remaining ¹⁴⁴Sm interference on ¹⁴⁴Nd, using the ¹⁴⁴Sm/¹⁴⁹Sm ratio of 0.2301. The mass fractionation of ¹⁴⁴Sm/¹⁴⁹Sm was corrected by ¹⁴⁷Sm/¹⁴⁹Sm normalization, using the ¹⁴⁴Sm/¹⁴⁹Sm ratio of 1.08680 and exponential law. All data reduction for the MC-ICP-MS analysis of Nd isotope ratios was conducted using Iso-Compass software (Zhang et al. Reference Zhang, Hu and Liu2020). Two natural apatite megacrysts, Durango and MAD, were used as the unknown samples to verify the accuracy of the calibration method for in situ Nd isotope analysis of the apatites. The chemical and Nd isotopic compositions of Durango and MAD have been reported by Xu et al. (Reference Xu, Hu, Zhang, Yang, Liu and Gao2015).

In this study, we chose six samples, QG-1-1, QG-1-2, QG-2-1, QG-3-4, QG-4-2 and QG-6-1, to analyse the S isotopes of pyrite and chalcopyrite in the thin-sections. In situ sulfur isotope analyses of pyrite and chalcopyrite were performed on a Neptune Plus MC-ICP-MS (Thermo Fisher Scientific, Bremen, Germany) equipped with a GeoLasHD excimer ArF laser ablation system (Coherent, Göttingen, Germany) at the Wuhan Sample Solution Analytical Technology Co., Ltd, Hubei, China. In the laser ablation system, helium was used as the carrier gas for the ablation cell and was mixed with argon (makeup gas) after the ablation cell. The single spot ablation mode was used. Then a large spot size (33 μm) and slow pulse frequency (8 Hz) were used to avoid the downhole fractionation effect that has been reported by Fu et al. (Reference Fu, Hu, Zhang, Yang, Liu, Li, Zong, Gao and Hu2016). One hundred laser pulses were completed in one analysis. A new signal-smoothing device was used downstream from the sample cell to efficiently eliminate the short-term variation of the signal, especially for the slow pulse frequency condition (Hu et al. Reference Hu, Zhang, Liu, Gao, Li, Zong, Chen and Hu2015). The laser fluence was kept constant at ∼5 J cm⁻². A standard-sample bracketing method was employed to correct for instrumental mass fractionation. To avoid the matrix effect, a pyrite standard PPP-1 and a chalcopyrite standard GBW07268 (a pressed pellet) were chosen as reference materials for correcting the natural pyrite samples and the natural chalcopyrite samples, respectively. The reference values of δ³⁴S_v-CDT in these standards have been reported by Fu et al. (Reference Fu, Hu, Zhang, Yang, Liu, Li, Zong, Gao and Hu2016). More details of the in situ S isotopic ratio analysis were described in Fu et al. (Reference Fu, Hu, Zhang, Yang, Liu, Li, Zong, Gao and Hu2016). All data reduction for the MC-ICP-MS analysis of the S isotope ratios was conducted using Iso-Compass software (Zhang et al. Reference Zhang, Hu and Liu2020).

5.a. Zircon U–Pb age and trace elements

The zircon U–Pb isotope and trace-element analysis results are listed in online Supplementary Material Tables S1 and S2, respectively. Zircon grains in the gabbro sample can be divided into two groups under CL imaging (Fig. 5b). Group A is euhedral, colourless and transparent with a length of 80–110 μm and length-to-width ratios of 1:1–1.2:1. Group A contains 19 grains, which are bright in the CL images with clear oscillatory zoning, indicating their magmatic origin (Andersson et al. Reference Andersson, Miller and Johansson2002; Wu & Zheng, Reference Wu and Zheng2004). In Group A, almost all zircons show low La contents and high (Sm/La)_N and Ce/Ce* values (Fig. 5b), which are similar to those of typical magmatic zircons. Distinct positive Ce (Ce/Ce* = 77 on average) anomalies and obvious negative Eu (Eu/Eu* = 0.33 on average) anomalies are also observed. Nineteen analyses on 19 grains with clear oscillatory zoning yielded a group of ²⁰⁶Pb–²³⁸U ages ranging from 806 to 812 Ma. This group of ages yielded a weighted mean ²⁰⁶Pb–²³⁸U age of 810 ± 4 Ma (MSWD = 0.11, n = 19; Fig. 5a). The measured U, Th and Th/U values for these zircon grains range from 214 to 1005 ppm, from 106 to 748 ppm, and from 0.37 to 0.96, respectively. This weighted mean ²⁰⁶Pb–²³⁸U age of 810 ± 4 Ma was interpreted as the crystallization age of the gabbro. Group B contains one zircon grain (QG-1-18), which is characterized by a dark inherited core cut by a newly grown rim in the CL images. One significantly older ²⁰⁷Pb–²⁰⁶Pb age of the dark inherited core is 2335 Ma. This zircon is believed to have been captured from the source area or wall rock.

Fig. 5. (a) Zircon U–Pb concordia diagrams and (b) chondrite-normalized (Sun & McDonough, Reference Sun, McDonough, Saunders and Norry1989) zircon REE patterns and cathodoluminescence (CL) images of zircons for the dated gabbro. (c) Photomicrograph of apatite grains imaged by CL, with the circles showing the locations of LA-ICP-MS ²⁰⁶Pb–²³⁸U dating. Ap – apatite; Cal – calcite; Phl – phlogopite. (d) Apatite U–Pb concordia diagrams for the dated phosphate ores.

5.b. Apatite U–Pb age

Apatite U–Pb dating results are listed in online Supplementary Material Table S3. Some apatite grains in a disseminated ore sample contain slightly higher common Pb and varying Pb/U, and choosing an initial Pb isotopic composition to calculate the age may not be appropriate (Banerjee et al. Reference Banerjee, Simonetti, Furnes, Muehlenbachs, Staudigel, Heaman and van Kranendonk2007; Li et al. Reference Li, Li, Wu, Yin, Ye, Liu, Tang and Zhang2012; Chen & Simonetti, Reference Chen and Simonetti2013). Thus, we use the ²⁰⁷Pb-correction method to calculate the apatite age (Chen & Simonetti, Reference Chen and Simonetti2013). The uncorrected data are plotted in the Tera-Wasserburg diagram, and these analyses yielded a lower intercept age that approximates the apatite age. The y-intercept initial ²⁰⁷Pb/²⁰⁶Pb can be used to obtain the individual ²⁰⁷Pb-corrected ²⁰⁶Pb–²³⁸U ages, which can be used to calculate the weighted average age of the apatite (Grunenfelder et al. Reference Grunenfelder, Tilton, Bell and Blenkinsop1986; Chen & Simonetti, Reference Chen and Simonetti2013).

Apatite grains from the disseminated ore sample are colourless and predominantly prismatic euhedral crystals, and the CL images (Fig. 5c) show that the compositions of the apatites are homogeneous. All 15 analyses on 10 apatite grains (Fig. 5c) contain a significant amount of common Pb, deviating from the U–Pb age concordia line. All analyses plot on a line on the Tera-Wasserburg concordia diagram, yielding a lower intercept age of 818 ± 39 Ma (Fig. 5d). ²⁰⁶Pb–²³⁸U ages after correction of common Pb (Chen & Simonetti, Reference Chen and Simonetti2013) vary from 820 to 791 Ma, yielding a weighted mean age of 810 ± 5 Ma (MSWD = 1.3, n = 15; Fig. 5d). This weighted mean ²⁰⁶Pb–²³⁸U age of 810 ± 5 Ma was interpreted as the crystallization age of the apatite.

5.c. Mineral major-element compositions

5.c.1. Olivine

Major-element compositions of eight olivine grains, four from sample QG-4-2 (Fig. 3h, I; Table 1) and four from sample QG-6-1 (Fig. 3g; Table 1), are listed in Table 2. The major-element contents of the olivine grains from these samples are basically the same, and all the analysed olivine grains are chrysolite according to their ratios between forsterite and fayalite. Forsterite percentages and CaO contents of the olivines are consistent from 89 % to 91 % and 0.03–0.10 wt %, respectively. The high forsterite percentages of the olivines indicate the ultrabasic deep source of the parental magma forming the QMC, and the consistent compositions of the olivines in the two lithologies might indicate the same magmatic source.

Table 2. Major-element compositions (wt %) of olivines from the QMC

5.c.2. Pyroxene

Major-element compositions of 21 pyroxene grains, 15 from samples QG-1-1 and QG-1-2 (Table 1) and 6 from samples QG-3-1 and QG-3-2 (Table 1), are listed in online Supplementary Material Table S4 and are illustrated in Figures 6 and 7. The major-element data for 21 pyroxene grains from these samples exhibit large compositional ranges, i.e. SiO₂ = 50.35–53.45 wt %, CaO = 17.31–21.74 wt %, MgO = 8.71–16.52 wt %, FeO = 8.55–14.69 wt % and Al₂O₃ = 1.40–4.54 wt %. Clinopyroxenes of the clinopyroxenites have relatively low Mg no. values (53–57) and plot into the field of diopside in the Wo–En–Fs diagram, while clinopyroxenes of the gabbros have relatively high Mg no. values (61–76) and all plot into the field of augite in the Wo–En–Fs diagram (Fig. 6). As CaO contents increase, SiO₂ and Al₂O₃ contents of the clinopyroxenes in the gabbros and clinopyroxenites show opposite trends (Fig. 7b, e), which should be related to the occupation of Si and Al^IV (Al in the tetrahedral sites) in the clinopyroxene structure due to the formation of the two lithologies at different pressures. Compared with the clinopyroxenes of the clinopyroxenites, the clinopyroxenes of the gabbros have lower CaO and FeO contents (Fig. 7d) and higher MgO and TiO₂ contents (Fig. 7a, h). The lower CaO contents of the clinopyroxenes in the gabbros might be related to the crystallization of apatite, clinopyroxene and calcite in the early stage of magma evolution, and the lower TiO₂ contents of the clinopyroxenes in the clinopyroxenites could be related to the earlier or simultaneous crystallization of ilmenite rather than clinopyroxene (Fig. 4e; Pang et al. Reference Pang, Li, Zhou and Ripley2009).

Fig. 6. Wo–En–Fs diagram showing the compositions of clinopyroxenes from the QMC.

Fig. 7. (a–h) Binary variation diagrams (TiO₂, Al₂O₃, V₂O₃, FeO, SiO₂, MnO, Na₂O and MgO versus CaO) for clinopyroxenes from the QMC.

5.d. Whole-rock geochemistry and Sr–Nd isotopes

The whole-rock major- and trace-element data from this work and previously published papers (Jiang et al. Reference Jiang, Lu, Bai, Zhang, Ye, Feng and Chen2005; Zhang et al. Reference Zhang, Li, Li, Lu, Ye and Li2007; Sun & Zhou, Reference Sun and Zhou2008, Fu, Reference Fu2012) are presented in online Supplementary Material Table S8 and are illustrated in Figures 8 and 9 and online Supplementary Material Figure S3. The low loss on ignition (LOI) values (mostly less than 1.74 wt %) of the clinopyroxenite and gabbro samples indicate insignificant alteration, consistent with their petrographic characteristics. The low LOI values of the carbonatite samples (less than 1.68 wt %) after removing the CO₂ content in calcite and H₂O content in apatite indicate that the alteration is insignificant, which is also consistent with the lithofacies characteristics (Fig. 3h, i; Zhang et al. Reference Zhang, Li, Li, Lu, Ye and Li2007; Ye et al. Reference Ye, Li and Lan2013; W. Chen, unpub. Ph.D. thesis, China Univ. Geosciences, 2021). While the high LOI values (14.59–22.60 wt %) and CaO contents (1.25–23.79 wt %) of the serpentinized dunite samples, which might be caused by the injection of calcite and significantly influenced by fluid-related alteration (Fig. 3g; Huang et al. Reference Huang, Sun, Gu, Wang and Cao2001, Reference Huang, Wu, Lei, Chen, Xiong, Qin and Gu2012; Q. Yuan, unpub. Ph.D. thesis, China Univ. Geosciences, 2016; W. Chen, unpub. Ph.D. thesis, China Univ. Geosciences, 2021), indicate that these samples do not represent magmatic compositions. The major-element data for the silicate rocks from the QMC exhibit large compositional ranges, i.e. SiO₂ = 24.90–54.43 wt %, Al₂O₃ = 0.38–16.38 wt %, CaO = 0.05–27.40 wt %, MgO = 3.35–37.13 wt %, Fe₂O₃ ^T = 1.23–14.12 wt %, TiO₂ = 0.05–2.77 wt %, P₂O₅ = 0.02–7.17 wt %, K₂O = 0.07–10.15 wt % and Na₂O = 0.00–4.77 wt %. They are characterized by large ranges of Mg no. values (40–99) and Ni (0.01–1812 ppm) and V (0.01–1281 ppm) contents. The highest content of MgO in the clinopyroxenites and serpentinized dunites reaches 34.20 wt % and 37.13 wt %, respectively, possibly due to the cumulation of clinopyroxene or olivine. In the AFM (Na₂O + K₂O–FeO–MgO) diagram, the clinopyroxenite and gabbro samples follow a tholeiitic trend (online Supplementary Material Fig. S3). Large variations in REE contents (∑REE = 1 to 8433 ppm) reflect different abundances and compositions of intercumulus liquids. Silicate rocks from the QMC are generally enriched in light REEs (LREEs) relative to heavy REEs (HREEs), with (La/Yb)_N values ranging from 10 to 84 (Fig. 8a, c). The clinopyroxenites, gabbros and serpentinized dunites show similar REE distribution patterns, and the clinopyroxenites have higher REE contents than the gabbros and serpentinized dunites (Fig. 8a, c). The REE distribution patterns of the most silicate rocks show slight negative Eu anomalies, while the serpentinized dunites show obvious or slight positive Eu anomalies, indicating that plagioclase did not undergo obvious fractional crystallization in the early stage of magmatic evolution. Similar to the REE distribution patterns, primitive mantle-normalized spider diagrams (Sun & McDonough, Reference Sun, McDonough, Saunders and Norry1989) of the silicate rocks for incompatible elements also exhibit variable abundances, reflecting different abundances and compositions of intercumulus liquids (Fig. 8b, d). As shown in Figure 9a, b, the REE contents are positively correlated with P₂O₅ concentrations, and the (La/Sm)_N values versus La contents show a good linear correlation, indicating apatite accumulation, because all REE partition coefficients for apatite are higher than 1.0 (Brassinnes et al. Reference Brassinnes, Balaganskayab and Demaiffea2005). In the silicate rocks, Ba is anomalously enriched relative to Rb and Th, and P is anomalously enriched relative to Sr and Nd (Fig. 8b, d). Primitive mantle-normalized incompatible element spider diagrams exhibit variable abundances (e.g. Rb, Ba, Th, U) and depletion in Nb, Ta, Zr, Hf and Ti due to fractional crystallization and/or mineral accumulation. The gabbros have variable positive Sr anomalies, whereas the clinopyroxenites have obvious negative Sr anomalies (Fig. 8b).

Fig. 8. (a, c) Chondrite-normalized REE patterns and (b, d) primitive mantle-normalized incompatible element spider diagrams for the rocks from the QMC. The normalizing values are from Sun & McDonough (Reference Sun, McDonough, Saunders and Norry1989).

Fig. 9. (a) ∑REE versus P₂O₅ discrimination diagram. (b) (La/Sm)_N versus La discrimination diagram after Treuil & Joron (Reference Treuil and Joron1975). (c) ∑REE versus P₂O₅ discrimination diagram. FC – fractional crystallization; IM – liquid immiscibility; PM – partial melting.

The carbonatite samples have relatively consistent CaO (44.68–52.10 wt %) and MgO (2.46–4.68 wt %), but variable ∑REE (809–4266 ppm), TiO₂ (0.07–0.68 wt %), SiO₂ (0.14–4.36 wt %) and Fe₂O₃ (0.51–7.61 wt %). Major-element compositions indicate a calcic nature according to the classification scheme suggested by Gittins & Harmer (Reference Gittins and Harmer1997). As shown in Figure 8c, carbonatites have pronounced fractionation between LREEs and HREEs with (La/Yb)_N values ranging from 16 to 232 and insignificant negative Eu anomalies. On primitive mantle-normalized incompatible element spider diagrams, the carbonatites are enriched in Ba but depleted in Nb, Zr, Hf and Ti relative to the neighbouring elements (Fig. 8d). The carbonatites and clinopyroxenites show similar REE and trace-element distribution patterns, indicating that they were likely derived from the evolution of the same magma. Unlike the clinopyroxenites, the carbonatites are extremely depleted in Zr, Hf, Nb and Ti, while enriched in Ta (Fig. 8b, d). The depletion of Ti might be due to crystal fractionation of rutile and/or titanite. Compared with silicate rocks, the carbonatites have higher LREE contents, which might be related to the gradual enrichment of volatiles during the evolution of the magma because LREEs are easier to be enriched in the volatile-rich melt proposed by Cullers & Graf (Reference Cullers and Graf1984). The trace-element compositions of the carbonatites are similar to those of the average calcio-carbonatites documented by Woolley & Kempe (Reference Woolley, Kempe and Bell1989). As noted by Woolley & Kempe (Reference Woolley, Kempe and Bell1989) and Harmer (Reference Harmer1999), care should be taken when using such an average composition because of the extreme ranges observed in certain elements in carbonatites (e.g. Nb, Sr and Ba). For example, the carbonatites exhibit a Nb content of less than 24.40 ppm, which is much lower than the average Nb content of carbonatites (1204 ppm; Woolley & Kempe, Reference Woolley, Kempe and Bell1989). Compared with the carbonatites, the disseminated phosphate ores show higher contents of REEs, P, Ta, Zr, Hf and Ti, which should be related to the higher proportion of apatite and Fe–Ti oxides. As shown in Figure 8, the phosphate ore samples show similar REE and trace-element distribution patterns to the carbonatite and clinopyroxenite samples.

The calculated ϵ_Nd(t) and (⁸⁷Sr/⁸⁶Sr)_i values and the reported whole-rock Sr–Nd isotopic data of the QMC (Ye et al. Reference Ye, Li and Lan2013) are listed in Table 3 and are illustrated in Figure 10. The clinopyroxenite and gabbro samples exhibit a wide range of Sr–Nd isotopic compositions (ϵ_Nd(t) = −1.91 to −16.91; (⁸⁷Sr/⁸⁶Sr)_i = 0.70481 to 0.70710). The carbonatite samples also exhibit a wide range of Nd isotopic compositions (ϵ_Nd(t) = −0.20 to −11.80) and relatively low initial ⁸⁷Sr/⁸⁶Sr ratios ((⁸⁷Sr/⁸⁶Sr)_i = 0.70581 to 0.70648), in which sample QG-4-5 has the lowest ϵ_Nd(t) value (−0.20). Overall, these rock samples have ϵ_Nd(t) and (⁸⁷Sr/⁸⁶Sr)_i values in the ranges of −0.20 to −16.91 and 0.70581 to 0.70710, respectively, and plot within the enriched mantle quadrant of the anti-correlation diagram (Fig. 10; sample QG-1-2 is not plotted). In terms of the Sr–Nd isotopic compositions of the QMC, the ϵ_Nd(t) values have a larger variation range than the (⁸⁷Sr/⁸⁶Sr)_i values, and the silicate rocks have a relatively larger variation range than the carbonatites in (⁸⁷Sr/⁸⁶Sr)_i values.

Table 3. Whole-rock Sr–Nd isotopic data for the QMC

Fig. 10. Plot of ϵ_Nd(t) values versus (⁸⁷Sr/⁸⁶Sr)_i values of the QMC and apatites from the Kawuliuke 810 Ma pyroxenite (W. Chen, unpub. Ph.D. thesis, China Univ. Geosciences, 2021), northeastern Tarim Block. Depleted MORB mantle (DMM), high-µ (HIMU), enriched mantle I (EMI) and enriched mantle II (EMII) components are from Zindler & Hart (Reference Zindler and Hart1986) and DePaolo (Reference DePaolo1979). Base plot is after Hart & Zindler (Reference Hart, Zindler and Peltier1989). MORB – mid-ocean ridge basalt; OIB – ocean island basalt.

5.e. Zircon Hf isotopes

The zircon Hf isotopic data for the gabbro are listed in Table 4 and are illustrated in Figure 11. The calculated ϵ_Hf(t) values of the zircon grains in the gabbro sample range from −7.5 to −10.3. The reported ϵ_Hf(t) values of baddeleyites in the carbonatite and zircons in the clinopyroxenite range from −6.7 to −12.9 and −6.8 to −12.4 (Ye et al. Reference Ye, Li and Lan2013), respectively, consistent with the ϵ_Hf(t) values of zircons in the gabbro and whole-rock enriched Sr–Nd isotopic characteristics (Figs 10, 11).

Table 4. LA-ICP-MS Lu–Hf isotopic compositions of zircon grains for the gabbro

Fig. 11. ϵ_Hf(t) versus crystal age plots for dated zircon samples (after Long et al. Reference Long, Yuan, Sun, Kröner, Zhao, Wilde and Hu2011 a). DM – depleted mantle; CHUR – chondritic uniform reservoir.

5.f. Trace-element compositions and Sr–Nd isotopes of apatite

Trace-element compositions of 13 apatite grains, nine from samples QG-2-1 and QG-2-2 (Figs 3l, 4a, b; Table 1) and four from sample QG-3-4 (all apatite grains are enclosed in clinopyroxene crystals; Fig. 4c, d; Table 1), are listed in online Supplementary Material Table S9. The ∑REE contents of apatite grains from these samples vary widely from 2540 to 6540 ppm, and the ∑REE and HREE contents of apatite grains enclosed in clinopyroxene crystals of the magnetite- and apatite-bearing clinopyroxenite are obviously higher than those of apatites in the disseminated ores (Fig. 12). The Sr contents of apatite grains from these samples also vary widely from 2135 to 4020 ppm, while the V contents vary narrowly from 2.11 to 3.56 ppm. The Sr and V contents of apatites in the disseminated ores are slightly higher than those of apatites enclosed in clinopyroxenes. The apatite grains from the two different types of samples are fairly homogeneous in each trace-element composition (Fig. 12). All apatites of the disseminated ores have consistent LREE-enriched patterns with La/Yb ratios of 92 to 152, and negligible Eu anomalies with Eu/Eu* values of 0.88 to 0.92. The apatites enclosed in clinopyroxenes also have consistent LREE-enriched patterns with La/Yb ratios of 32 to 54, and slightly obvious Eu anomalies with Eu/Eu* values of 0.72 to 0.74. Compared with the apatites enclosed in clinopyroxenes of the magnetite- and apatite-bearing clinopyroxenites, the higher La/Yb ratios of the apatites in the disseminated ores indicate their more obvious differentiation of LREEs and HREEs. The La/Yb ratios and Sr contents of apatites in the disseminated ores show a significant positive correlation with ∑REE contents (Fig. 13a, b), and the La/Yb ratios also show a significant positive correlation with Sr contents and Sm/Yb ratios (Fig. 13c, d).

Fig. 12. Chondrite-normalized REE distribution patterns of apatites from the QMC. The chondrite data are from Sun & McDonough (Reference Sun, McDonough, Saunders and Norry1989).

Fig. 13. Binary variation diagrams for apatites from the QMC: (a) Sr versus ∑REE; (b) La/Yb versus ∑REE; (c) La/Yb versus Sr; (d) Sm/Yb versus La/Yb. Data for apatites in ore and carbonatite from Q. Yuan (unpub. Ph.D. thesis, China Univ. Geosciences, 2016), Ye et al. (Reference Ye, Li and Lan2013) and W. Chen (unpub. Ph.D. thesis, China Univ. Geosciences, 2021).

In situ Sr–Nd isotopic compositions of 25 apatite grains, 18 from samples QG-2-1 and QG-2-2 (all analysed apatite grains are enclosed in olivine and calcite crystals; Fig. 4a, b; Table 1) and seven from sample QG-3-4 (all analysed apatite grains are enclosed in clinopyroxene crystals; Fig. 4c, d; Table 1), are listed in online Supplementary Material Table S10. Eighteen in situ Nd isotopic analyses of apatite grains from the disseminated ore samples yield a range of ϵ_Nd(t) values from −7.73 to −10.24, and the cumulative probability histogram displays a normal distribution with an average value of −8.94 (n = 18; Fig. 14a). In situ analysis of apatite grains from the disseminated ore samples give (⁸⁷Sr/⁸⁶Sr)_i values from 0.70509 to 0.70628, and the weighted mean value of these (⁸⁷Sr/⁸⁶Sr)_i values is 0.70602 ± 0.00003 (n = 18; Fig. 14b). Seven in situ analyses of apatite grains from the magnetite- and apatite-bearing clinopyroxenite sample yield a relatively smaller range of Sr and a larger range of Nd isotopic compositions compared to those from the disseminated ore samples. These apatites enclosed in clinopyroxenes have ϵ_Nd(t) values ranging from −7.96 to −8.79, and the cumulative probability histogram also displays a normal distribution with an average value of −8.38 (n = 7; Fig. 14c). Additionally, these apatites show a smaller range of (⁸⁷Sr/⁸⁶Sr)_i values of 0.70587 to 0.70597, with a weighted mean value of 0.70592 ± 0.00005 (n = 7; Fig. 14d). On the whole, the (⁸⁷Sr/⁸⁶Sr)_i values of the apatites enclosed in olivines and calcites of the disseminated ores are higher than those of apatites enclosed in clinopyroxenes of the magnetite- and apatite-bearing clinopyroxenite, while the ϵ_Nd(t) values are lower. However, the average (⁸⁷Sr/⁸⁶Sr)_i value and the weighted mean ϵ_Nd(t) value of the apatite grains from these samples generally overlap with each other (Figs 10, 14). Compared with the whole-rock Sr–Nd isotopes of the clinopyroxenites ((⁸⁷Sr/⁸⁶Sr)_i = 0.70603 to 0.70710, average value is 0.70670; ϵ_Nd(t) = −7.50 to −10.30, average value is −9.30), the (⁸⁷Sr/⁸⁶Sr)_i values of the apatites enclosed in clinopyroxenes are generally lower and the ϵ_Nd(t) values are generally higher (Figs 10, 14). Unlike the clinopyroxenites, the initial Sr–Nd isotopic ratios of apatites enclosed in olivines and calcites are similar to the whole-rock Sr–Nd isotopes of the carbonatites ((⁸⁷Sr/⁸⁶Sr)_i = 0.70581 to 0.70648, average value is 0.70609; ϵ_Nd(t) = −7.60 to −11.8, average value is −9.13). The Sr–Nd isotopic compositions of the whole-rock and apatites all plot within the enriched mantle quadrant of the anti-correlation diagram (Fig. 10).

Fig. 14. (a) Cumulative probability histogram of ϵ_Nd(t) values of apatites enclosed in olivines and calcites of ore. (b) Weighted mean diagram of (⁸⁷Sr/⁸⁶Sr)_i values of apatites enclosed in olivines and calcites of ore. (c) Cumulative probability histogram of ϵ_Nd(t) values of apatites enclosed in clinopyroxenes of clinopyroxenite. (d) Weighted mean diagram of (⁸⁷Sr/⁸⁶Sr)_i values of apatites enclosed in clinopyroxenes of clinopyroxenite.

5.g. S isotopes of pyrite and chalcopyrite

In situ S isotopic compositions of 34 pyrite and chalcopyrite grains (online Supplementary Material Fig. S4a; Table 1), six from sample QG-4-2, five from sample QG-3-4, seven from sample QG-6-1, eight from samples QG-1-1 and QG-1-2, and eight from sample QG-2-1, are listed in online Supplementary Material Table S11. The δ³⁴S values of a small amount of pyrites and chalcopyrites in these samples mainly vary from +0.7 ‰ to +3.0 ‰ (online Supplementary Material Fig. S4c), which are similar to the δ³⁴S values (+1.3 ‰ to +2.86 ‰) of pyrites in clinopyroxenite reported by Chen (Reference Chen1989), belonging to sulfur from the mantle. Some pyrites and chalcopyrites have higher δ³⁴S values of +3.2 ‰ to +6.6 ‰, which are higher than the δ³⁴S value of sulfur from the mantle. These high δ³⁴S values are relatively concentrated (online Supplementary Material Fig. S4c), which might be hydrothermal sulfur (online Supplementary Material Fig. S4b), as Liu & Wen (Reference Liu and Wen2007) and Huang et al. (Reference Huang, Wu, Lei, Chen, Xiong, Qin and Gu2012) pointed out that hydrothermal alteration existed in the late evolution of the Qieganbulake magma. In fact, a small number of subhedral sulfide grains with high δ³⁴S values (+3.2 ‰ to +6.6 ‰) are distributed in different lithofacies of the Qieganbulake complex (online Supplementary Material Table S11), and they are usually distributed in patchy textures and an obvious metasomatic structure around the Fe–Ti oxides (online Supplementary Material Fig. S4b), obviously indicating that these sulfides were formed by late magmatic hydrothermal sulfur. According to the results of our in situ sulfide S isotope analysis, the primary compositions of the sulfide minerals are magmatic, though a late hydrothermal overprint for some points cannot be ruled out. One previous study showed high chalcophile elements (Q. Yuan, unpub. Ph.D. thesis, China Univ. Geosciences, 2016) in the magnetite of the QMC rocks, indicating equilibration with co-magmatic sulfide mineral assemblages (Bhattacharjee & Mondal, Reference Bhattacharjee and Mondal2021).