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Article

Geochemical Characteristics and Zircon U-Pb Geochronology of Diabase in the Jinchanghe Mining Area, Western Yunnan, SW China: Implications for Tectonic and Magmatic Evolution of the Baoshan Block

by
Xuelong Liu
1,
Wenchang Li
1,2,*,
Yunman Zhou
3,
Chengfeng Zhao
3,
Jun Zhu
1,*,
Fanglan Li
1,
Jiyuan Wang
3,
Qingrui Li
3,
Zhiyi Wei
3,
Xue Liu
1,
Hai Wang
3 and
Jun Fu
3
1
College of Land and Resources Engineering, Kunming University of Science and Technology, Kunming 650093, China
2
Chengdu Geological Survey Center of China Geological Survey, Chengdu 610051, China
3
Yunnan Gold & Mining Industry Group Co., Ltd., Kunming 650299, China
*
Authors to whom correspondence should be addressed.
Minerals 2022, 12(2), 176; https://doi.org/10.3390/min12020176
Submission received: 15 December 2021 / Revised: 18 January 2022 / Accepted: 28 January 2022 / Published: 29 January 2022
(This article belongs to the Section Mineral Geochemistry and Geochronology)
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Abstract

:
The Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit is located in the northern Baoshan block in the Sanjiang metallogenic belt, southwestern China, and is one of the major large-scale Pb-Zn polymetallic deposits. This region is characterized by numerous diabase intrusions; however, research work is limited. This study elucidated systematic geochemistry and chronology of the diabase closely associated with orebodies in Jinchanghe to provide constraints for magma evolution. The results indicated that the Jinchanghe diabase was enriched in CaO, MgO, and Al2O3 and depleted in TiO2 and P2O5. Large ion lithophile elements were depleted, while for high field strength elements, the ratio of LREEs but depleted in HREEs. The zircon U-Pb dating results suggested that the diabase age could be divided into two stages, indicating the occurrence of two-stage tectonic-magmatic events in the Late Triassic and Early Cretaceous. The results also suggested that the metallogenic age of the Jinchanghe deposit is the Early Cretaceous. Moreover, the age was closely related to the collision after the closure of the mid-Tethys Ocean in the Early Cretaceous. Therefore, the results of this study provide new evidence for the tectonic-magmatic evolution and mineralization of the Baoshan block.

1. Introduction

The Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit is located in the northern Baoshan block and is part of the “Sanjiang” (i.e., Jinsha, Lancang, and Nujiang River) polymetallic metallogenic belt in southwest China. It is also a typical representative Pb-Zn polymetallic deposit in the Baoshan block. The Yunnan Gold Mining Group Co., Ltd. has conducted a series of explorations in the Jinchanghe mining area since 2004. Previous studies on mineralogical characteristics and alteration zoning have indicated that the ore body is characterized by Pb, Zn-Cu, and Cu-Fe vertical zoning and Fe, Cu-Pb, and Zn-Cu horizontal zoning [1,2]. Additionally, the mineralization age has been assigned to the Early Cretaceous [3]. Studies on the alteration zoning of the deposit have speculated that the Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit is skarn-type [4]. In this type of mineral deposit genesis, there is a significant regional negative gravity anomaly according to gravity anomaly data, which may have a close genetic relationship with lead-zinc polymetallic deposits [5]. Due to the low degree of research in the mining area, so far the mineralization-related intermediate-acidic rock mass is not revealed. The surface of the mining area can be seen in diabase island-lenticular distribution. After detailed observation under a microscope, the main components of diabase are determined as pyroxene and basic feldspar. In addition, the diabase intrusion in the mining area is generally in close contact with the ore bodies. The exposed area is approximately 0.11–0.39 km2 with ecliptic alterations. However, systematic research on the diabase in the mining area is limited.
Therefore, this study conducted a systematic geochemical analysis of the diabase in the Jinchanghe mining area and determined its zircon U-Pb age. Additionally, its tectonic setting and material source area were determined, and the relationship between the Fe-Cu-Pb-Zn polymetallic deposit and the diabase intrusion was analyzed. The results of this study provide a baseline reference for further understanding of the genesis of deposits in the study region.

2. Regional Geological Background

The Baoshan block is an important part of the Tethys in western Yunnan [6,7,8]. It is located in the middle of the Tibetan-Yunnan-Thai-Ma middle plate and extends southward from the border to connect with Shan State and subsequently form the SIBMASU terrane [9,10]. The eastern side is bounded by the Kejie-Nandinghe fault, which is adjacent to the Changning-Menglian belt. The western side is connected with the Tengchong block and is separated by the Lushui-Luxi-Ruili fault. The merging of the Lancangjiang and Nujiang faults resulted in the extinction of the northern part of the Baoshan block in the Bijiang area (Figure 1). Under the influence of regional tectonic evolution, this area has mainly experienced two long geological evolution processes: Cambrian to Early Permian Proto-Tethys and Paleo-Tethys stable platform and platform basin stage, and Late Early Permian to Triassic Paleo-Tethys subduction collision stage [11].
The main faults in the study area are Lancangjiang and Nujiang, while the secondary faults are Kejie and Wayao-Yunxian. The regional fault structure line is affected by the main faults and exists in the NE, NW, SN, and EW directions [5]. The Baoshan-Shidian complex anticline, which is north of Wafang and south of Mengxing, is the main fold in the region. Its control boundaries are all faults, and the overall extension is close to the SN direction.
Additionally, several secondary folds and main veins are visible at the secondary fold axis or the anticline-syncline transition. Strata ranging from the Paleozoic to the Cenozoic are exposed, and the Gongyangmenghe group (Z-Єgy) in the Sinian-Cambrian represents the oldest stratum. Among these, the Early Paleozoic stratum indicates the widest range of exposure as well as the most complete development, characterized by the presence of shallow-semi-deep marine carbonates, clastic rocks, siliceous rocks, and shale deposits [12]. Most carbonates and clastic rocks have metamorphosed into marble, marbled limestone, and silty slate [13].
Magmatic rocks are widely exposed in the study area and developed from the Precambrian to the Mesozoic. The Precambrian is characterized by Laojiezi and Luxi granites with Rb-Sr isochron ages of 687 and 645 Ma, respectively [1]. Pinghe granite from the Early Paleozoic is the most widely distributed granite body in the Baoshan block, and its zircon U-Pb age range is 466–502 Ma [14,15,16,17]. The Late Paleozoic magmatic rocks include Muchang alkaline granite, Daxueshan ultrabasic rock mass, and Dashan rock mass [11]. The Mesozoic and Cenozoic magmatic rocks are represented by the Zhibenshan granite body in the northern Baoshan block, two-mica granites in the Yunlong metallogenic belt [18], Shuangmaidi rock mass [18], and monzonitic granite of the Longling-Luxi area [18,19]. In addition, numerous diabases with rock walls and veins are produced in the area.

3. Geological Features of Jinchanghe Deposit and Petrographic Characteristics of the Diabase

The Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit is located in the northern Baoshan block at the intersection of the Muguashu-Zhushiqin (SN direction) and Muguashu-Ashizhai (NW direction) faults (Figure 2). The faults controlled the development of the derivative secondary structure of the deposit, while the fractures formed a herringbone. The Cambrian, Ordovician, Silurian, Devonian, and Quaternary strata are predominantly exposed in the mining area. Metamorphic carbonate rocks in the middle section of the Upper Cambrian Formation (Є3h2) constitute the main ore-bearing horizon of the deposit.
The fault structures in the mining area are largely present in the NW, NE, and SN directions. Among these, faults F2 and F10, with evident ore-control characteristics, are the main ore-controlling structures. The F2 fault declines to the SW with a dip angle of 74°. Additionally, its structural fracture zones are well developed in the northwest segment and accompanied by diabase intrusion. The F10 fault declines to the SE with a dip angle of 70° and indicates characteristics of torsional normal fault activity. Jinchanghe uplift is the main fold in this region. The stress concentration acts on the axial part of the fold to result in the formation of tensile cracks, which provide favorable ore-bearing space for the deposit.
Magmatic rocks in the mining area are largely island-like with a lenticular distribution of diabase and an exposed area ranging from 0.11 to 0.39 km2. The lenticular diabase intrusions are mainly distributed in the tunnel (Figure 3a). The rock is gray-green with idiomorphic or hypidiomorphic granular and block structures (Figure 3b). The diabase indicated residual diabasic texture under the microscope (Figure 3d), and its main minerals were plagioclase (30 wt%), pyroxene (20 wt%), and minor minerals such as amphibole, biotite, and quartz. Among these, plagioclase was partially altered into albite and zoisite, while pyroxene was partially altered to amphibole (Figure 3c,d).

4. Sample and Analysis Method

4.1. Sample Collection

In order to systematically study the geochemical characteristics and chronology of the Jinchanghe diabase, eighteen representative samples were collected from typical boreholes in different ore sections of the Jinchanghe mining area. The samples were taken from ZK4k-7x drill holes, ZK4k-13x drill holes, ZK4k-9xx drill holes, ZK2k-8xs1 drill holes, ZK8-4 drill holes, and ZK3k-11x (sample information is shown in Table 1). The collected samples had no cracks and were relatively fresh, so they were well represented. Samples JCH6-01 diabase (from ZK4k-7x drill holes, depth of 25 m) and JCH7-07 diabase (from ZK8-4 drill holes, depth of 491 m) were used for zircon dating.

4.2. Analytical Method

4.2.1. Zircon U-Pb Ages and Hf Isotopic Composition

Zircons were separated by conventional heavy liquid and magnetic techniques before the separations were purified by handpicking under a binocular microscope. The resulting zircons were mounted in epoxy resin, polished, gold-coated, and then photographed under transmitted and reflected light. Zircon internal textures were examined through cathodoluminescence (CL) imaging prior to U-Pb isotopic analysis. Zircon U-Pb dating, and trace element analysis of zircon were simultaneously conducted by LA-ICP-MS at the Wuhan SampleSolution Analytical Technology Co., Ltd., Wuhan, China. Detailed operating conditions for the laser ablation system and the ICP-MS instrument and data reduction were the same as those described by Zong et al. (2017) [20]. Laser sampling was performed using a GeolasPro laser ablation system that consists of a COMPexPro 102 ArF excimer laser and a MicroLas optical system. Zircon 91500 and glass NIST610 were used as external standards for U-Pb dating and trace element calibration, respectively. A piece of Excel-based software ICPMSDataCal was used to perform off-line selection and integration of background and analyzed signals, time-drift correction, and quantitative calibration for trace element analysis and U-Pb dating [21].
Zircon Lu-Hf isotope analysis was completed at the State Key Laboratory of Geological Processes and Mineral Resources (GPMR) of China University of Geosciences (Wuhan), and the experiment was completed using the coherent 193 nm excimer laser ablation system (GeoLasPro HD) and Neptune Plus multi-receiver plasma mass spectrometry. The diameter of the laser ablation spot beam was 44 μm, and the detailed parameters of the instrument are shown in Liu et al. (2010b) [22]. The sample tested used 91,500 and the international zircon standard GJ-1 as the standard at the same time, of which the weighted average of 176Hf/177Hf tested for 91500 was 0.282308 ± 12 (2σ), and the weighted average of 176Hf/177Hf test of GJ-1 was 0.282013 (2σ). The Zircon Hf isotope analysis point was on and near the Zircon U-Pb isotope age analysis point with the same structure. The data processing was completed using the software ICPMSDataCal 12.0 for the experimental process and data processing method.

4.2.2. Whole-Rock Geochemistry Analysis

Samples of major and trace element geochemistry were collected from Jinchanghe diabase. Whole-rock major and trace element analyses were conducted at the ALS minerals laboratory, Guangzhou, China. Further, major oxides were analyzed by X-ray fluorescence spectroscopy (XRF), with analytical uncertainties of <0.5% used. Trace element concentrations were determined by Inductively Coupled Plasma-Atomic Emission Spectroscopy (ICP-AES).

5. Results

5.1. Geochemical Characteristics

The analysis of the main trace elements in Jinchanghe diabase (Table 2) indicated that the SiO2 content ranged between 42.02 wt% and 48.43 wt%, with an average of 44.54 wt% obtained, and the Al2O3 content ranged between 10.96 wt% and 17.14 wt%, with an average of 13.59 wt% obtained. The TiO2 content ranged between 1.08 wt% and 2.74 wt%, with an average of 1.95 wt% obtained. Additionally, the K2O content ranged between 0.079 wt% and 1.58 wt%, with an average of 0.51 wt% obtained, while that of Na2O ranged between 1.02 wt% and 3.61 wt%, with an average of 2.16 wt% obtained. The Na2O content was higher than that of K2O. Moreover, the results indicated a higher alkali content, and the total alkali (Na2O+K2O) content ranged between 1.48 wt% and 4.04 wt%, with an average of 2.68 wt% obtained. The rocks were relatively enriched in Na and depleted in K. Furthermore, the Na2O/K2O ratio ranged from 1.53 to 37.72. The P2O5 content ranged from 0.10 wt% to 0.36 wt%, with an average of 0.22 wt% obtained. The analysis of geochemical characteristics suggested that the Jinchanghe diabase is enriched in CaO, MgO, and Al2O3 and depleted in TiO2 and P2O5.
Eighteen samples were plotted on the Gabbro region in the intrusive rocks TAS diagram (Figure 4a). Among these, ten samples were assigned to the alkaline area, while the remaining samples were assigned to the sub-alkaline region. Additionally, the evolution of alkaline to sub-alkaline indicated that the basic magma experienced moderate differentiation during diagenesis of the Jinchanghe diabase. The data for the SiO2-K2O diagram (Figure 4b) were plotted on the calc-alkaline and low-potassium series. The Mg# values ranged between 48.22 and 71.21, with an average of 56.42 obtained, and were lower than that of the original magma [23]. The Hark diagram for the main elements indicated (Figure 5) that CaO, Al2O3, and MgO were negatively correlated, thus suggesting plagioclase crystallization differentiation. However, P2O5, FeOT, and MgO indicated positive correlations, which suggested that the basic magma was characterized by apatite and Fe oxide separation and crystallization during the formation process.
The trace element analysis results for Jinchanghe diabase are presented in Table 1. The total quantity of rare earth elements (∑REE) ranged from 54.39 ppm to142.32 ppm, with an average of 99.90 ppm obtained. The ratio of quantities of light rare earth elements (LREE) and heavy rare earth elements (HREE) ranged between 2.46 and 7.98, with an average of 5.67 obtained. The (La/Yb)N values ranged between 1.63 and 13.49, thus indicating evident fractionation of the LREEs and HREEs. The δEu values ranged from 0.76 to 1.45, with an average of 1.02 obtained. The REE patterns exhibited LREE enrichment and indicated no obvious plagioclase crystallization in the original magma (Figure 6a).
Large ion lithophile elements, such as Ba, K, and Sr, were depleted in the primitive mantle, as indicated by the standardized spider diagram of trace elements (Figure 6b). Additionally, K was strongly depleted, while high field strength elements (HFSE), such as Th, Nd, and Hf, were enriched. The correlation diagram between MgO and the trace elements (Cr, Nb, Ni, Co, and V) (Figure 7) indicated positive correlations. Additionally, decreases in Cr and Ni indicated the occurrence of olivine and clinopyroxene crystallization differentiation in the basic magma.
In Table 2, 10.47 wt% and 15.65 wt%, with an average of 12.99 wt% obtained and was higher than that of the continental crust (6.7 wt%). The Cu content ranged from 27.3 ppm to 149.0 ppm, with an average of 80.83 ppm obtained, and was higher than the Cu content of the continental crust (27 ppm). The Pb content ranged from 1.1 ppm to 17.4 ppm, with an average of 6.14 ppm obtained, and was less than its content in the continental crust (11 ppm). The Zn content ranged between 63 ppm and 153 ppm, with an average of 113.21 ppm obtained, and was higher than the Zn content of the continental crust (72 ppm) [21]. Therefore, Fe, Cu, and Zn indicated high geochemical background values, thus suggesting that the diabase could be a source of ore-forming materials for the Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit.

5.2. Zircon U-Pb Ages

In this study, twenty-four zircons were obtained from two diabase samples (JCH6-01, JCH7-07) for conducting the dating analysis. These included nineteen zircon samples from JCH6-01 and five from JCH7-07. Each zirconium was measured at one point. The analysis results are presented in Table 3. Figure 8 presents a zircon cathodoluminescence image with the zircon length ranging from 50 to 150 μm and a high aspect ratio (1 to 2.5). Eighteen zircons indicated a good degree of self-formation and were characterized by clear oscillating ring zones and obvious characteristics of magmatic zircon. The 206Pb/238U ages of 12 zircons from the JCH6-01 sample were found to be from 203 ± 5.0 to 240 ± 4.0 Ma. The age distribution was concentrated, and the 12 points were distributed on and around the consistent curve and indicated good concordance. Additionally, their weighted mean age was determined to be 216.9 ± 2.7 Ma (n = 12, MSWD = 1.5) (Figure 9a). The other five zircons from the JCH6-01 sample were largely semi-automorphic, the ring zones were not clear or undeveloped, and two zircons (6-01-6, 6-01-23) indicated spongy zircon secondary development. The structure showed characteristics of hydrothermal origin zircon. Their 206Pb/238U ages were found to range from 124 ± 5.0 to 144 ± 2.0 Ma, and the points were distributed on and near the harmonic curve. The weighted mean age was determined to be 130.5 ± 8.8 Ma (n = 5, MSWD = 0.34) (Figure 9a). This indicates that the Jinchanghe mining area experienced hydrothermal activity during this period and that the metallogenic time limit of the Jinchanghe Pb-Zn polymetallic deposit was the Early Cretaceous.
The 206Pb/238U ages of the five zircons from the JCH7-07 sample were found to range from 211 ± 3.2 to 217 ± 3.1 Ma, and the age distribution was concentrated. The five points were distributed on and around the consistent curve with good concordance, and the weighted mean age was found to be 213.9 ± 2.9 Ma (n = 5, MSWD = 0.51) (Figure 9b). Thus, the results indicate that the crystallization age of the diabase is 213.9 ± 2.9 Ma, and that the diabase is a product of the Late Triassic magmatism.

5.3. Zircon Hf Isotopes

This paper analyzed the Lu-Hf isotopes of two zircon samples. As part of the analysis, points were pierced by the laser beam spot, and 23 effective analysis points were finally obtained. The analysis data are shown in Table 4. Zircon Lu-Hf isotope analysis data show that the early Paleozoic zircon 176Yb/177Hf ratio was between 0.051648 and 0.094189, the average was 0.073504, the 176Lu/177Hf ratio was between 0.001681 and 0.003074, and the average was 0.002402; the late Triassic zircon 176Yb/177Hf ratio was between 0.034114 and 0.069213, the average was 0.052969, the ratio of 176Lu/177Hf was between 0.001293 and 0.002607, and the average was 0.002018; the ratio of Early Cretaceous zircon 176Yb/177Hf was between 0.024444 and 0.060041, the average was 0.042568, the ratio of 176Lu/177Hf was between 0.000857 and 0.002276, and the average was 0.001608. The ratio of 176Lu/177Hf of all zircon analysis points was less than 0.004, indicating that after the formation of zircon, there was only a small amount of radioactive Hf accumulation. Therefore, the initial 176Hf/177Hf ratio obtained by analysis and testing can be used to represent the Hf isotope composition of the system when zircon was formed.
The Hf isotope calculation was based on the age of a single zircon. As shown in the frequency distribution histogram of zircon εHf(t) values (Figure 10a), the range of zircon εHf(t) value changes of three different ages were compared. The zircon εHf(t) values of the Early Paleozoic age were between −4.69 and −1.71, the average was −3.49, and they were mainly distributed between −3 and −5; the zircon εHf(t) values of the Late Triassic age were between 2.4 and −13.0, the range of variation was large, and the average was 8.8; the zircon εHf(t) values of the Early Cretaceous age were between 1.4 and 10.4, and the average was 5.5. In the characteristic map of zircon Hf isotopic composition (Figure 10b), the casting points of zircons of the Late Triassic and Early Cretaceous ages were found to fall between the chondrite evolution line and the depleted mantle evolution line. The single-stage Hf isotope model age TDM was found to range between 350 and 781 Ma, with averages of 523 Ma and 391 to 750 Ma obtained. The two-stage Hf isotope model ages of TCDM were found to range between 428 and 1093 Ma, with averages of 694 Ma and 526 to 1104 Ma obtained.

6. Discussion

6.1. Time Limits of Diagenesis

The diabase in the study area is an intrusive rock mass closely symbiotic with the ore body. However, estimates of its precise isotopic age limits are limited [1]. Previous stratigraphic studies have indicated the diabase to be a Hercynian intrusive rock mass. In this study, the U-Pb ages of zircons obtained by LA-ICP-MS were determined to be 216.9 ± 2.7 Ma and 213.9 ± 2.9 Ma, thus indicating that emplacement crystallization of the Jinchanghe diabase occurred in the Late Triassic. This result is consistent with the time limits of the closing of the ancient Tethys Ocean [27]. The extension or extensional structure of the Baoshan block could be attributed to collisional orogeny between the Baoshan and Simao blocks. These structures caused an upwelling of the basic mantle source magma to form the diabase intrusion during this time limitation.
In this study, the U-Pb age of the hydrothermal zircon was determined to be 130.5 ± 8.8 Ma, thus indicating the occurrence of strong hydrothermal activity or mineralization during this time zone. The results also suggest that the metallogenic time limit of the Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit is Early Cretaceous. This age is consistent with the Rb-Sr isochron line age of sphalerite (117–120 Ma) [5], thus providing further evidence for the metallogenic time limits of the Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit. Previous research in the study region has indicated the Rb-Sr isochronic ore-forming ages of the Hetaoping and Luziyuan Pb-Zn deposits to be 116.1 ± 3.9 Ma [11] and 141.9 ± 2.6 Ma [28], respectively. These results are consistent with the hydrothermal zircon age (136.3 ± 9.4 Ma) obtained in this study and suggest that the typical representative Pb-Zn polymetallic deposits in the region are products of geological events in the same period.

6.2. Tectonic Environment

The basic rock wall resulted from the rapid emplacement of magma from a deep source to the shallow part of the crust due to tectonic continental crust extension [29]. Therefore, the study of the geochemical characteristics and chronology of the basic rock can elucidate its geotectonic background and formation time limits.
In this study, basalt-type geotectonic environments were classified as oceanic and continental and were found to be characterized by a Th/Ta ratio of 1.6 for the original mantle. Basalt in the continental plate is divided across the continental rift and the internal thermal column. The Th/Ta ratio of the Jinchanghe diabase was found to range from 1.12 to 4.38, with an average of 1.96 obtained, indicating a wide range of variation. The Ta/Hf ratio of the diabase was found to range between 0.44 and 2.02, with an average of 0.79 obtained, which indicated that the Jinchanghe diabase presented characteristics of continental rift basalt. Furthermore, the trace element tectonic environment discrimination diagram (Figure 11) indicated that all sample points for the Jinchanghe diabase were plotted on the within-plate basalt area, thus suggesting that the rocks indicated characteristics of within-plate basalt. In addition, the Jinchanghe diabase lacked HFSEs, which is consistent with the characteristics of continental rift basalt [30]. Therefore, considering the diabase distribution near the transtensional fault, these results suggest that the Jinchanghe diabase was formed in an extensional tectonic setting.

6.3. Magma Sources

The geochemical properties of basalts are predominantly affected by the composition of the mantle region from which they are derived. Additionally, their composition varies with the tectonic setting [31]. The ratio of highly incompatible elements is generally stable during the process of magma separation and partial melting. Therefore, end-member types of ocean island basalts (OIB) are often distinguished by ratios of highly incompatible elements such as Th, Ta, Nb, Ba, Rb, and La. According to the Hofmann mantle model, the OIBs can be divided into three different end members: HIMU OIB, EMI OIB, and EMII OIB [32]. Weaver concluded that the HIUM OIB was derived from the subduction of the ancient oceanic shell to the lower mantle, while the EMI OIB and EMII OIB originated from the subduction and dehydration of the ancient oceanic crust, respectively. Moreover, EMI OIB is characterized by the presence of deep-sea sediments, while EMII OIB is characterized by the occurrence of terrigenous clastics [33].
All points in the Ta/Yb-Th/Yb diagram (Figure 12) were plotted on the enriched mantle source area, thus indicating that the Jinchanghe diabase was formed by the partial melting of the enriched mantle. A comparison of ratios between them and OIB terminal elements and the major incompatible elements (Table 5) suggests that the Jinchanghe diabase belongs to the enriched HIMU mantle.
The Mg# values of the Jinchanghe diabase ranged between 48.22 and 71.21, with an average of 56.42 obtained. Additionally, the Mg# standard values of between 68 and 75 were lower than those of the original magma and indicated an association with moderately evolved magma [35]. The Th/Ta ratio of the Jinchanghe diabase ranged between 1.12 and 4.38, with an average of 1.96 obtained, while the Th/Ta ratios of the original mantle and continental crust are known to be 2.3 and 10 [24], respectively, thus suggesting that the Jinchanghe diabase was less likely to be contaminated by the Earth’s crust. Additionally, the Zr/Hf ratio of the Jinchanghe diabase ranged between 15.81 and 36.84, with an average of 31.78 obtained, which are higher values than those obtained for the crust (11) and close to those obtained for the original mantle (36.73) [33]. Therefore, it is less likely that the Jinchanghe diabase was contaminated by crustal materials.
Previous studies have shown that the Lu-Hf isotope group in zircon can better indicate the source of magma and its mixing process. The analysis results of the Hf isotopic composition of the Jinchanghe diabase zircon show that the εHf(t) values of the magmatic zircon and the hydrothermal zircon ranged, respectively, between 2.4 and 13.0 and 1.4 and 8.1, both of which are positive. The age of TCDM (428–1093Ma, 526–1104 Ma) was found to be greater than the crystallization age (182–233 Ma, 124–144 Ma). In the zircon t-εHf(t) diagram, all sample casting points fall below the depleted mantle evolution line. The above characteristics indicate that the magma source area of the Jinchanghe diabase either was contaminated by ancient crustal materials or originated from the enriched mantle. There are obvious inheritance or capture zircons on the zircon CL. The crystallization age of the inherited or captured zircon was determined to be between 497 ± 11 and 448 ± 6 Ma, which is the same as the crystallization age of the granite body in the Baoshan block (447–486 Ma) [36]. Further, its εHf(t) values ranged between −5.5 and −1.3. On the zircon t-εHf(t) diagram, all points are placed under the chondrite evolution line, indicating that the parent magma that inherits or captures zircon originated from the partial melting of ancient crustal material. Based on the above characteristics, it is believed that the Jinchanghe diabase originated from an enriched mantle source area and may have been contaminated by crustal materials during the ascent of magma.
Finally, the cathodoluminescence map of zircon indicated that the internal structure of magmatic zircon in the Jinchanghe diabase was uniform, and no early formation of zircon tuberculosis was observed. These results also indicate that it is less likely that the Jinchanghe diabase was contaminated by the Earth’s crust [37]. This could be attributed to the faster emplacement of magma in the upward direction, which could have resulted in a lower degree of contamination by the Earth’s crust. In summary, the Jinchanghe diabase magma originated from the enriched mantle, which was less likely to be contaminated by crustal materials during magma evolution and predominantly reflected characteristics of the source zone.

6.4. Regional Tectonic-Magma Evolution and Mineralization

Previous studies have indicated that the Baoshan block experienced the geological tectonic evolution of the ancient Tethys, the central Tethys, and the new Tethys [38]. The structure in the area is relatively developed, and magmatism is frequent.
The Paleo-Tethys oceanic plate subduction and orogenic formation in the Early Paleozoic (502–448 Ma) formed the Pinghe adamellite [14,15,16,17]. The Baoshan block experienced a quiet period of magmatism from 440 to 270 Ma. Notably, the Gengma monzonitic granite rock mass developed on the southeastern margin of the Baoshan block; its U-Pb age has been determined to be between 232 and 230 Ma, and its genesis was related to the closure of the Paleo-Tethys Ocean [39]. The Paleo-Tethys Ocean closed in the Late Triassic and the oceanic crust subducted beneath the Qiangtang-Baoshan block. Additionally, the oceanic crust partially melted to generate the basic magma. Subsequently, magma rising and emplacement along the weak tectonic fault zone formed the diabase. Combined with zircon U-Pb dating data of this study, it shows that Jinchanghe diabase is the product of Late Triassic magmatic activity. The magmatic activity and mineralization in the Early Cretaceous were relatively developed. The closure of the Middle Tethys Ocean affected the thickening of the crust on the western side of the Baoshan block, which led to the re-melting of the crust and consequent initiation of magmatism, mixed lithification, and mineralization. The magmatic event during this period was mainly represented by the development and formation of the Zhibenshan biotite granite and the Kejie biotite granite in the northwest Baoshan block. The zircon U-Pb age of the Zhibenshan granite has been determined to be 126.7 ± 1.6 Ma, while that of the Kejie biotite granite, which formed in the shear extension structure of the Middle Tethys Ocean, has been determined to be 93 ± 13 Ma. This has further been related to the deep melting of the crustal material caused by the thickening of the Earth’s crust [40]. In this study, the hydrothermal zircon U-Pb age of the Jinchanghe diabase was determined to be 130.5 ± 8.8 Ma, which indicates that the mining area experienced a strong hydrothermal event in the Early Cretaceous. Considering the regional tectonic evolution, the Bangonghu-Nujiang Ocean of the Middle Tethys closed in the Early Cretaceous, and the collision between the Tengchong and Baoshan blocks formed the Gaoligong collisional tectonic belt [41,42]. Additionally, the collision resulted in internal crustal thickening and periodic shearing in the interior of the Baoshan block [43]. Therefore, it is speculated that the formation of the Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit was related to tectonic-magmatic events caused by the shortening and thickening of the inner crust of the Baoshan block in the Early Cretaceous.

7. Conclusions

(1)
The zircon U-Pb ages of the Jinchanghe diabase were found to be 216.9 ± 2.7 Ma, 213.9 ± 2.9 Ma, and 130.5 ± 8.8 Ma, thus indicating that the region experienced two-stage tectonic-magmatic events in the Late Triassic and Early Cretaceous. The Late Triassic represented the crystallization and emplacement stages of the diabase, while the Early Cretaceous represented the hydrothermal zircon formation period after the hydrothermal superposition reformation.
(2)
The tectonic environment discrimination diagram of strongly incompatible elements suggested that the Jinchanghe diabase was characterized by a series of calc-alkaline basalts from the continental plate and was formed during the upwelling of mantle materials under extensional tectonic settings. Moreover, the magma indicated fast upward emplacement. Thus, it was less likely to be contaminated by the crust and predominantly reflected characteristics of the source region.
(3)
The Paleo-Tethys Ocean closed in the Late Permian-Late Triassic, and the Burmese-Thaima micro-continent (the Baoshan block) collided with the main body of the Simao block. The collisional orogenic effects resulted in stretching inside the Baoshan block, and the Jinchanghe basic primitive magma was raised along the weak tectonic fault zone to form the diabase during this period.
(4)
The closure of the Middle Tethys Ocean in the Early Cretaceous resulted in a collision between the Baoshan and Tengchong blocks. Consequently, crustal thickening and shearing extension occurred inside the Baoshan block, which experienced a strong hydrothermal event. This enabled the formation of the Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit.

Author Contributions

X.L. (Xuelong Liu) contributed to the conception of the study; C.Z., J.W., Q.L., Z.W., H.W. and J.F. contributed significantly to field geological work; F.L. and X.L. (Xue Liu) performed the data analyses and wrote the manuscript; W.L., J.Z. and Y.Z. helped perform the analysis with constructive discussions. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

The data provided in this study can be obtained from the figures and the tables in the article.

Acknowledgments

This paper is supported by a study on metallogenic regularity of Jinchanghe iron copper lead zinc polymetallic deposit in Baoshan block, western Yunnan (KKF0202121297); Study on multi-stage composite mineralization of sigzan porphyry copper molybdenum ore belt in Yunnan Province (2019FA018); Hydrothermal alteration zoning and metallogenic fluid of Yanshanian porphyry Mo-Cu deposit in Tongchanggou, Zhongdian, Northwest Yunnan (2019FB062); Natural Science Foundation of China (Grant No.41862009), Science and Technology Award of Yunnan Province-Outstanding Contribution award Project (Grant No. 2007001).

Conflicts of Interest

The authors declare no competing financial interests.

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Figure 1. Geotectonic location of the Baoshan block, Yunnan (after [1]).
Figure 1. Geotectonic location of the Baoshan block, Yunnan (after [1]).
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Figure 2. Simplified geological map of the Jinchanghe Fe-Cu-Pb-Zn deposit.
Figure 2. Simplified geological map of the Jinchanghe Fe-Cu-Pb-Zn deposit.
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Figure 3. Filed photographs and photomicrographs of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. (a) The lens of diabase intrusion in the 1660 m level, (b) The diabase exposed in the drill hole of ZK4k-13x, (c) The zoisitization of plagioclase and the amphibolization of pyroxene in diabase, (d) The diabasic structure formed by subhedral pyroxene crystals filled in a triangular hole composed of platy plagioclase crystals and the albitization of plagioclase. Pl—Plagioclase; Aug—Augite; Hb—hornblende; Zo—zoisite; Ab—Albite.
Figure 3. Filed photographs and photomicrographs of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. (a) The lens of diabase intrusion in the 1660 m level, (b) The diabase exposed in the drill hole of ZK4k-13x, (c) The zoisitization of plagioclase and the amphibolization of pyroxene in diabase, (d) The diabasic structure formed by subhedral pyroxene crystals filled in a triangular hole composed of platy plagioclase crystals and the albitization of plagioclase. Pl—Plagioclase; Aug—Augite; Hb—hornblende; Zo—zoisite; Ab—Albite.
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Figure 4. (a) TAS diagram and, (b) SiO2-K2O diagram of the diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. 1—Olive gabbro; 2—Gabbro; 3—Gabbro-diorite; 4—Diorite; 5—Granodiorite; 6—Granite; 8—Foid gabbro; 9—Monzogabbro; 10—Monzodiorite; 11—Monzonlite; 12—Quartz monzonite; 13—Foidit; 14—Foid monzodiorite; 15—Foid nepheline syenite; 16—Syenite; 17—Foid syenite.
Figure 4. (a) TAS diagram and, (b) SiO2-K2O diagram of the diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. 1—Olive gabbro; 2—Gabbro; 3—Gabbro-diorite; 4—Diorite; 5—Granodiorite; 6—Granite; 8—Foid gabbro; 9—Monzogabbro; 10—Monzodiorite; 11—Monzonlite; 12—Quartz monzonite; 13—Foidit; 14—Foid monzodiorite; 15—Foid nepheline syenite; 16—Syenite; 17—Foid syenite.
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Figure 5. Hark diagrams of major elements of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Figure 5. Hark diagrams of major elements of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
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Figure 6. (a) Chondrite-normalized rare earth distribution pattern, (b) Primitive mantle-normalized trace element spider diagram of diabase in the Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit (after [24]).
Figure 6. (a) Chondrite-normalized rare earth distribution pattern, (b) Primitive mantle-normalized trace element spider diagram of diabase in the Jinchanghe Fe-Cu-Pb-Zn polymetallic deposit (after [24]).
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Figure 7. Diagrams of trace elements and MgO of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Figure 7. Diagrams of trace elements and MgO of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
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Figure 8. Cathodoluminescence (CL)images of zircon with U-Pb analyzed from the diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Figure 8. Cathodoluminescence (CL)images of zircon with U-Pb analyzed from the diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
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Figure 9. Concordia plot of zircon 206Pb/238U-207Pb/235U of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. (a) sample of JCH6-01 diabase, (b) sample of JCH7-07 diabase.
Figure 9. Concordia plot of zircon 206Pb/238U-207Pb/235U of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. (a) sample of JCH6-01 diabase, (b) sample of JCH7-07 diabase.
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Figure 10. The frequency distribution histogram of the zircon εHf(t) of the Jinchanghe diabase (a) and the characteristic diagram of the Hf isotopic composition of the zircon (b).
Figure 10. The frequency distribution histogram of the zircon εHf(t) of the Jinchanghe diabase (a) and the characteristic diagram of the Hf isotopic composition of the zircon (b).
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Figure 11. Discrimination diagram of trace elements of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. (a) CAB—Calc-Alkali Basalts; IAT—Island Alkali Tholeiites; WPAB—Within Plate Tholeiite-Basalts; N-MORB—Normal Mid Ocean Ridge Basalts; E-MORB+WPT—Enriched Mid-Ocean Ridge Basalts + Within Plate Tholeiites. (b) Discriminant diagrams of tectonic settings. (c) A1 + A2—Within Plate Alkali-Basalts; A2+C—Within Plate Tholeiite-Basalts; D—Normal Mid Ocean Ridge Basalts; C+D—Volcanic Arc Basalts. (d) CAB—Calc-Alkali Basalts; OFB—Ocean Floor Basalts; LKT—Low-potassium Tholeiites, Island Arc Tholeiites; WPB—Within Plate Basa.
Figure 11. Discrimination diagram of trace elements of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. (a) CAB—Calc-Alkali Basalts; IAT—Island Alkali Tholeiites; WPAB—Within Plate Tholeiite-Basalts; N-MORB—Normal Mid Ocean Ridge Basalts; E-MORB+WPT—Enriched Mid-Ocean Ridge Basalts + Within Plate Tholeiites. (b) Discriminant diagrams of tectonic settings. (c) A1 + A2—Within Plate Alkali-Basalts; A2+C—Within Plate Tholeiite-Basalts; D—Normal Mid Ocean Ridge Basalts; C+D—Volcanic Arc Basalts. (d) CAB—Calc-Alkali Basalts; OFB—Ocean Floor Basalts; LKT—Low-potassium Tholeiites, Island Arc Tholeiites; WPB—Within Plate Basa.
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Figure 12. Ta/Yb-Th/Yb Bivariate Graphical of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. IAB—Island-Arc Basalts; IAT—Island Alkali Tholeiites Series; ICA—Island Arc Calc-Alkali Series; SHO—Shoshonite Series; WPB—Within Plate Basalts; MORB—Median Mid-Basalts; TH—Tholeiite Basalt; TR—Transition Median Mid-Basalt Basalt; ALK—Alkaline Basalt.
Figure 12. Ta/Yb-Th/Yb Bivariate Graphical of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit. IAB—Island-Arc Basalts; IAT—Island Alkali Tholeiites Series; ICA—Island Arc Calc-Alkali Series; SHO—Shoshonite Series; WPB—Within Plate Basalts; MORB—Median Mid-Basalts; TH—Tholeiite Basalt; TR—Transition Median Mid-Basalt Basalt; ALK—Alkaline Basalt.
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Table
Table 1. Sample statistics of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Table 1. Sample statistics of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Sample NumberRock TypeSampling Location
JCH6-01Gray-green diabaseZK4k-7x drill holes, depth of 25 m
JCH6-15Gray-green diabaseZK4k-13x drill holes, depth of 36.95 m
JCH6-27Gray-green diabaseZK4k-9xx drill holes, depth of 45 m
JCH6-36Gray-green diabaseZK4k-13s drill holes, depth of 30 m
JCH6-39Gray-green diabaseZK2k-8xs1 drill holes, depth of 28 m
JCH7-05-1Gray-green diabaseZK8-4 drill holes, depth of 1470 m
JCH7-05-2Gray-green diabaseZK8-4 drill holes, depth of 1472 m
JCH7-05-4Gray-green diabaseZK8-4 drill holes, depth of 1473 m
JCH7-07Gray-green diabaseZK8-4 drill holes, depth of 491 m
JCH7-13Gray-green diabaseMain roadway 150 m in the middle section of 1660
JCH8-4Gray-green diabaseZK2k-8xs1 drill holes, depth of 28 m
JCH8-27Gray-green diabaseZK2k-8xs1 drill holes, depth of 46 m
JCH8-29Gray-green diabaseZK2k-8xs1 drill holes, depth of 47 m
JCH8-37Gray-green diabaseZK2k-8xs1 drill holes, depth of 48 m
JCH8-39Gray-green diabaseZK3k-11x drill holes, depth of 45 m
JCH8-40Gray-green diabaseZK3k-11x drill holes, depth of 29 m
JCH8-41Gray-green diabaseZK3k-11x drill holes, depth of 32.5 m
JCH8-50Gray-green diabaseZK3k-11x drill holes, depth of 34 m
Table
Table 2. Major element oxides (wt%) and trace element (ppm) of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Table 2. Major element oxides (wt%) and trace element (ppm) of diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Sample
Number		JCH6-01JCH6-15JCH6-27JCH6-36JCH6-39JCH7-05-2JCH7-05-1JCH7-05-4JCH8-4JCH8-27JCH8-29JCH8-37JCH8-39JCH8-40JCH8-41JCH8-50JCH7-13JCH7-07
SiO245.6348.4343.9842.6643.447.0145.4546.824443.1244.7842.1643.144.2642.0247.1243.6144.31
Al2O315.0814.8813.1811.9113.2214.2717.1414.9711.2913.0415.0910.9612.5813.2513.9414.1712.3613.22
TiO22.41.712.262.151.982.031.151.671.852.252.282.271.892.172.741.231.082.07
FeOT12.3711.7814.1613.8513.0911.1211.1812.4813.8214.2212.4215.6512.9814.4414.9510.7410.9213.58
MgO6.756.5910.4311.359.136.85.847.5412.510.38.1112.59.7111.159.0912.8015.159.59
CaO11.969.638.0711.418.3613.131511.710.99.048.6610.88.948.2111.45.218.079.62
Na2O2.272.982.591.412.52.021.462.21.52.53.611.022.392.241.442.421.622.73
K2O0.4460.0790.4180.3670.9340.250.160.180.440.490.430.461.010.470.511.580.720.31
MnO0.430.2970.2030.1760.2040.180.190.20.210.220.170.240.210.310.520.130.150.26
P2O50.2040.2020.3190.2050.2930.260.110.150.230.280.360.180.280.240.20.110.10.31
LOI2.453.384.374.516.872.412.392.573.864.794.433.987.653.793.084.566.754.72
Total99.9999.9699.9810099.9899.47100.07100.48100.6100.25100.34100.22100.74100.5399.89100.07100.53100.72
Rb19.71.3411.414.167.39.817.48616.213.922.578.921.431.336.714.34.6
Ba15629.422825019429.618.221362227285207154.5232133.5349119257
Sr830397265464263469668416375373547377262298699196176332
Nb25.428.437.228.737.512.64.97.225.53241.921.631.328.1257.86.636.7
Th2.53.543.152.83.531.590.931.282.93.093.232.132.972.912.862.061.843.31
Pb7.8443.718.126.7710.217.47.17.15.24.55.35.45.56.91.61.12.7
Zn12212415312713685.86382123123991261201441417177121
Cu61.232.87212481.510642.627.310288.844.984.474.6116.527.6149143.576.2
Ni59.158.226026022479.363.288.3367268161319261283180.5394553234
Co44.338.669.574.561.892.925.638.769.564.348.774.758.359.365.360.459.157.3
V275257295353242386354343288318225423265347483313270276
Cr74.11534395143901571371887004662855784585512709341287428
U0.470.680.70.60.670.410.280.30.680.760.800.570.730.780.670.50.430.86
Ta1.831.62.4922.570.660.340.431.802.192.881.582.261.991.880.50.422.64
Zr77.449.196.487.9074.426.472951271511581181401451318974158
Hf2.681.753.413.122.581.672.12.83.74.34.33.83.84.33.72.72.24.4
La17.619.724.118.5258.166.36.919.723.326.516.523.52119.59.78.526.2
Ce33.538.147.732.949.219.816.317.940.147.854.834.246.543.138.820.417.853.4
Pr4.674.765.664.765.792.752.052.424.9967.064.355.825.494.952.722.356.56
Nd19.617.528.120.925.314.39.411.420.124.328.118.723.122.120.412.410.525.9
Sm4.184.415.574.885.764.173.023.394.865.636.514.565.195.415.053.683.116.23
Eu1.811.521.661.91.721.131.61.131.731.942.081.641.611.791.571.201.121.79
Gd4.264.255.244.44.994.973.794.514.665.656.294.874.835.404.744.753.775.89
Tb0.730.870.930.820.840.880.640.740.680.780.90.680.720.790.740.790.640.86
Dy4.064.784.164.054.365.954.124.733.794.384.873.733.684.413.974.974.094.48
Ho0.650.950.80.760.741.170.9310.670.770.90.660.670.800.681.050.880.79
Er1.742.671.871.771.823.42.642.881.631.852.111.631.681.921.72.992.461.96
Tm0.240.410.280.250.250.460.410.420.210.240.270.220.220.250.220.420.370.26
Yb1.242.251.571.441.52.862.772.581.21.411.681.231.251.451.312.612.281.52
Lu0.160.290.180.170.160.390.420.360.170.20.250.180.190.20.180.410.330.22
Y18.125.118.118.418.92923.725.116.118.721.816.416.919.517.126.622.519.7
ΣREE94.43102.45127.8397.49127.4370.454.3960.36104.49124.25142.3293.15118.96114.11103.8168.0958.2136.06
LREE81.3685.99112.7983.84112.7750.3138.6743.1491.48108.97125.0579.95105.7298.8990.2750.143.38120.08
HREE13.0716.4615.0413.6514.6620.0915.7217.2213.0115.2817.2713.213.2415.2213.5417.9914.8215.98
LREE/HREE6.235.227.56.147.692.502.462.517.037.137.246.067.986.56.672.782.937.51
(La/Yb)N10.186.2811.019.2211.952.051.631.9211.7811.8511.319.6213.4910.3910.682.672.6712.36
δEu1.31.060.921.230.960.761.450.881.11.040.981.060.9710.970.8810.89
Note: LOI = loss on ignition, total iron reported as FeOT.
Table
Table 3. LA-ICP-MS U-Pb data for zircon from diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Table 3. LA-ICP-MS U-Pb data for zircon from diabase in the Jinchanghe Fe-Cu-Pb-Zn deposit.
AnalysisPbThUTh/U207Pb/206Pb207Pb/235U207Pb/235U207Pb/235U206Pb/238U208Pb/232Th
×10−6Age (Ma)Age (Ma)Age (Ma)
JCH6-01
JCH6-01-01297.73305.02794.31.180.04880.00210.23730.01050.03500.0006216922242136
JCH6-01-02458.04455.04413.71.010.05670.00190.28790.00930.03680.0005257723332346
JCH6-01-03377.03412.54933.70.690.05070.00190.24430.00970.03470.0004222822032165
JCH6-01-04334.2271.33749.70.070.05750.00160.63210.01770.07900.000849711490562627
JCH6-01-05390.9492.04618.40.110.05540.00150.55370.01580.07200.000944710448646915
JCH6-01-09273.22517.32843.80.890.05030.00450.23020.02010.03320.00052101721132113
JCH6-01-1396.9473.6649.60.730.07230.01270.31970.05570.03210.00082824320351954
JCH6-01-1454.3476.5627.70.760.05330.00440.24350.01780.03440.00072211521842178
JCH6-01-15311.72778.84044.80.690.05030.00190.23550.00920.03370.0005215821332096
JCH6-01-1768.8420.0758.40.550.05930.00520.31000.02640.03790.00072742024042363
JCH6-01-20379.8722.11062.70.680.05100.00540.14430.01410.02050.001013712131613210
JCH6-01-21442.6726.31066.50.680.04870.00260.13640.00670.02030.0006130613041274
JCH6-01-22150.1194.4453.10.430.05260.00400.14310.01000.01970.0008136912651187
JCH6-01-23202.8609.41035.90.590.04610.00710.12290.01830.01940.00071181712451265
JCH6-01-24290.2774.71272.70.610.04900.00550.14150.01460.02090.001113413134712111
JCH6-01-33903.311,467.86957.61.650.05050.00160.23410.00710.03340.0004214621222025
JCH6-01-35565.05640.96216.10.910.07600.00380.35970.02110.03290.000631216209441743
JCH6-01-3844.7282.2614.30.460.05110.00400.26030.01980.03640.000823516230527718
JCH6-01-431081.911,318.57278.31.560.04610.00400.21880.01840.03450.00052011521832248
JCH7-07
JCH7-07-61509439700.970.04990.00220.23470.01060.03390.0005214921531998
JCH7-07-16895485850.940.05470.00260.25740.01180.03430.0005233102173331185
JCH7-07-201087076791.040.05420.00260.24930.01220.03330.0005226102113411300
JCH7-07-2516511169181.220.05380.00250.25030.01130.03360.000522792133501419
JCH7-07-28714784111.160.05850.00310.26890.01340.03360.0007242112134560494
Table
Table 4. LA-ICP-MS zircon Lu-Hf isotopic data of Jinchanghe diabase.
Table 4. LA-ICP-MS zircon Lu-Hf isotopic data of Jinchanghe diabase.
Sample176Yb/177Hf176Lu/177Hf176Hf/177Hf(176Hf/177Hf)iεHf(0)εHf(t)TDM (Ma)TCDM (Ma)f(Lu/Hf)
JCH6-010.0341140.0012930.2827540.0000100.282749−0.74.00.3443711995−0.96
JCH6-020.0392440.0014850.2827080.0000080.282702−2.42.60.29607811093−0.96
JCH6-030.0469990.0018730.2827680.0000090.282760−0.34.40.3121702970−0.94
JCH6-050.0491390.0019740.2828020.0000160.2827951.05.40.5734654898−0.94
JCH6-060.0515890.0019410.2829830.0000110.2829767.411.70.3955391493−0.94
JCH6-070.0692130.0024880.2830150.0000160.2830058.512.70.5566350428−0.93
JCH6-080.0541790.0020540.2830030.0000140.2829958.012.40.4848363448−0.94
JCH6-090.0803860.0027300.2823850.0000090.282362−13.8−4.70.320412841718−0.92
JCH6-100.0806940.0025870.2824130.0000100.282389−12.8−2.80.357112381630−0.92
JCH6-110.0503590.0017790.2829800.0000120.2829737.211.40.4270394504−0.95
JCH6-150.0595630.0026070.2827350.0000110.282726−1.42.40.39177661071−0.92
JCH6-170.0544530.0020540.2829840.0000140.2829757.411.90.4885391489−0.94
JCH6-180.0685780.0025230.2829740.0000180.2829647.011.50.6198410514−0.92
JCH6-190.0582060.0021470.2830060.0000160.2829978.213.00.5720359429−0.94
JCH6-040.091040.0011540.2827250.0000090.282722−1.81.40.32637501104−0.97
JCH6-120.0244440.0008570.2829230.0000120.2829215.28.10.4088465665−0.97
JCH6-130.0600410.0022760.2827640.0000120.282759−0.42.30.44137161034−0.93
JCH6-160.0566810.0021470.2829840.0000170.2829797.410.40.6130391526−0.94
JCH7-010.0941890.0030740.2824600.0000090.282433−11.2−1.70.322211851547−0.91
JCH7-020.0516480.0016810.2823790.0000090.282364−14.0−4.20.307212561701−0.95
JCH7-030.0686870.0022600.2823920.0000090.282372−13.6−3.90.333312571682−0.93
JCH7-040.0622840.0020130.2824080.0000100.282390−13.0−3.20.340412251642−0.94
JCH7-050.0766360.0024720.2823920.0000090.282370−13.5−4.00.309412641687−0.93
Notes:εHf(t) = 104 × {[(176Hf/177Hf)S − (176Lu/177Hf)S × (eλt − 1)]/[(176Hf/177Hf)CHUR − (176Lu/177Hf)CHUR × (eλt − 1)] − 1}, tDM = 1/λ × ln{1 + [(176Hf/177Hf)S − (176Hf/177Hf)DM]/[(176Lu/177Hf)S − (176Hf/177Hf)DM]}. tCDM = tDM − (tDM-t) × [(fccfs)/(fccfDM)]. fLu/Hf = (176Lu/177Hf)S/(176Lu/177Hf) CHUR-1. Among them: λ = 1.876 × 10−11a−1; (176Lu/177Hf)Sand(176Lu/177Hf)S are sample measurements; (176Lu/177Hf) CHUR = 0.332, (176Hf/177Hf) CHUR = 0.282772([25]); (176Hf/177Hf)DM = 0.0384, (176Hf/177Hf)DM = 0.28325; (176Hf/177Hf) average crustal thickness = 0.015([26]); fcc = [(176Lu/177Hf)average crustal thickness/(176Lu/177Hf) CHUR]-1; fs = fLu/Hf; fDM = [(176Lu/177Hf) DM /(176Lu/177Hf) CHUR] − 1; t refers to the crystallization age of zircon.
Table
Table 5. The ratios of incompatible elements of diabase and mantle endmember and main chemical reservoirs in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Table 5. The ratios of incompatible elements of diabase and mantle endmember and main chemical reservoirs in the Jinchanghe Fe-Cu-Pb-Zn deposit.
Zr/NbLa/NbBa/NbBa/ThTh/NbTh/LaBa/LaData Source
Primitive mantle14.80.948770.120.139.6Weaver, B.L. 1991 [33]
Depleted mantle301.074.3600.070.074
Continental crust16.22.2541244.70.225
HIMU OIB3.2~50.66~0.774.9~6.549~770.35~0.380.107~0.1336.8~8.7Plank, T., C. H. and Langmuir, C.H. 1998 [34]
EMI OIB5~13.10.78~1.329.1~23.480~2040.69~1.410.089~0.14711.2~19.1
EMII OIB4.4~7.80.79~1.016.4~11.357~1050.58~0.870.108~0.1837.3~13.5
Diabase of Jinchanghe1.73~14.690.63~1.291.04~44.748.31~169.420.08~0.280.12~0.221.49~35.98This paper
Average5.730.819.0167.540.130.1510.35
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Liu, X.; Li, W.; Zhou, Y.; Zhao, C.; Zhu, J.; Li, F.; Wang, J.; Li, Q.; Wei, Z.; Liu, X.; et al. Geochemical Characteristics and Zircon U-Pb Geochronology of Diabase in the Jinchanghe Mining Area, Western Yunnan, SW China: Implications for Tectonic and Magmatic Evolution of the Baoshan Block. Minerals 2022, 12, 176. https://doi.org/10.3390/min12020176

AMA Style

Liu X, Li W, Zhou Y, Zhao C, Zhu J, Li F, Wang J, Li Q, Wei Z, Liu X, et al. Geochemical Characteristics and Zircon U-Pb Geochronology of Diabase in the Jinchanghe Mining Area, Western Yunnan, SW China: Implications for Tectonic and Magmatic Evolution of the Baoshan Block. Minerals. 2022; 12(2):176. https://doi.org/10.3390/min12020176

Chicago/Turabian Style

Liu, Xuelong, Wenchang Li, Yunman Zhou, Chengfeng Zhao, Jun Zhu, Fanglan Li, Jiyuan Wang, Qingrui Li, Zhiyi Wei, Xue Liu, and et al. 2022. "Geochemical Characteristics and Zircon U-Pb Geochronology of Diabase in the Jinchanghe Mining Area, Western Yunnan, SW China: Implications for Tectonic and Magmatic Evolution of the Baoshan Block" Minerals 12, no. 2: 176. https://doi.org/10.3390/min12020176

APA Style

Liu, X., Li, W., Zhou, Y., Zhao, C., Zhu, J., Li, F., Wang, J., Li, Q., Wei, Z., Liu, X., Wang, H., & Fu, J. (2022). Geochemical Characteristics and Zircon U-Pb Geochronology of Diabase in the Jinchanghe Mining Area, Western Yunnan, SW China: Implications for Tectonic and Magmatic Evolution of the Baoshan Block. Minerals, 12(2), 176. https://doi.org/10.3390/min12020176

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