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Article

Geochronology, Geochemistry, and Tectonic Significance of Early Carboniferous Volcanic Rocks from the Ulanhot Region in the Central Great Xing’an Range

by
Yanqing Zang
1,2,
Tao Qin
3,*,
Cheng Qian
1,2,
Chao Zhang
1,2,
Jingsheng Chen
1,2 and
Wei Sun
1,2
1
Shenyang Geological Survey Center of China Geological Survey, Shenyang 110034, China
2
Northeast Geological S&T Innovation Center of China Geological Survey, Shenyang 110034, China
3
Military-Civilian Integration Geological Survey Center of China Geological Survey, Chengdu 610036, China
*
Author to whom correspondence should be addressed.
Minerals 2025, 15(6), 610; https://doi.org/10.3390/min15060610
Submission received: 16 April 2025 / Revised: 31 May 2025 / Accepted: 3 June 2025 / Published: 5 June 2025
(This article belongs to the Special Issue Granitoids and Their Importance in the Identification of Tectonic Environments, Geodynamic Evolution and Crustal Growth: Mineralizations, Geochronology, Elemental and Isotope Geochemistry)
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Abstract

:
The attributes of Late Paleozoic magmatic events are of paramount significance in elucidating the tectonic evolution of the Ulanhot region, which is located in the middle of the Hegenshan–Heihe tectonic belt (HHTB). This study undertook a comprehensive investigation of the petrography, LA–ICP–MS zircon U–Pb dating, whole rock geochemistry, and zircon Hf isotopes of the Early Carboniferous volcanic rocks. The volcanic rocks are predominantly composed of andesite, schist (which protolith is rhyolitic tuff), and rhyolitic tuff. The results of zircon U–Pb dating reveal that the formation ages of volcanic rocks are Early Carboniferous (343–347.4 Ma). Geochemical characteristics indicate that the andesites possess a comparatively elevated concentration of Al2O3, alongside diminished levels of MgO and TiO2, belonging to the high-K calc-alkaline series. The zircon εHf(t) of the andesites range from −13 to 9.4, while the two-stage Hf model ages span from 697 to 1937 Ma. The felsic volcanic rocks have high contents of SiO2 and Na2O + K2O, low contents of MgO and TiO2, and belong to high-K to normal calc-alkaline series. The zircon εHf(t) values of the felsic volcanic rocks range from −12.8 to 10, while the two-stage Hf model ages span from 693 to 2158 Ma. The Early Carboniferous volcanic rocks exhibit a notable enrichment in large ion lithophile elements (LILEs, such as Rb, K, Ba) and light rare earth elements (LREEs), depletion in high-field-strength elements (HFSEs, including Nb, Ta, Ti, Hf), as well as heavy rare earth elements (HREEs). The distribution patterns of the rare earth elements (REEs) demonstrate a conspicuous right-leaning tendency, accompanied by weak negative Eu anomalies. These characteristics indicate that the andesites represent products of multistage mixing and interaction between crustal and mantle materials in a subduction zone setting. The felsic volcanic rocks originated from the partial melting of crustal materials. Early Carboniferous igneous rocks formed in a volcanic arc setting are characteristic of an active continental margin. The identification of Early Carboniferous arc volcanic rocks in the Central Great Xing’an Range suggests that this region was under the subduction background of the oceanic plate subduction before the collision and amalgamation of the Erguna–Xing’an Block and the Songnen Block in the Early Carboniferous.

1. Introduction

The Central Asian orogenic belt (CAOB), commonly referred to as the Altai orogenic belt, is one of the subduction–accretionary orogenic belts with the longest development history and the most significant crustal accretion and transformation. This region is sandwiched between the Siberian Plate, the North China Plate, and the Tarim Plate [1,2,3,4], which has always been a concern (Figure 1a). The northeast region of China is situated within the eastern expanse of the CAOB, commonly referred to as the Xingmeng Orogenic Belt (XOB) [5,6]. The composition encompasses a series of microlandmasses, subduction–accretionary wedges, island arcs, ophiolites, and magmatic belts. The genesis and evolution of this region were predominantly governed by the tectonic influences of the Paleo–Asian Ocean, the Mongol–Okhotsk Ocean, and the Paleo–Pacific tectonic domain in Phanerozoic [7,8,9,10].
The northeast region of China is located in the eastern part of the CAOB, which can be divided into the Erguna Block, Xing‘an Block, and Songnen Block, progressing from north to south [11,12], of which the Erguna Block and the Xingan Block were bounded by the Xinlin–Xiguitu suture belt and collaged in the Early Paleozoic (500 Ma) [5,12,13], the boundary between the Erguna–Xing’an Block and the Songnen Block was the Hegenshan–Heihe tectonic belt (HHTB) [14,15,16,17]. Currently, there is controversy regarding the extension location and formation period of the HHTB. The southern part of this belt is named after the study of ophiolite in the Hegenshan area [18,19,20], and the northern part of this belt is mainly determined based on the studies of the Duobaoshan island arc, the Xinkailing Group, granitic mylonite, and the Nenjiang Complex [15,21]. However, for the middle section of the HHTB, due to the strong vegetation covering and the relatively little research on magma, structure, and paleogeographic environment, there are still many disputes about the extension location of the HHTB.
Regarding the distribution of paleo-suture zones and the amalgamation history of tectonic blocks in Northeast China, four main academic viewpoints have been proposed. The first suggests that the Hegenshan ophiolite suture zone predominantly extends eastward along the Hegenshan-Baicheng-Jilin-Yanji axis, ultimately being buried beneath Mesozoic-Cenozoic sedimentary strata of the Songliao Basin [6,22]. The second proposes an A-type granite belt stretching from East Junggar through Inner Mongolia to Northeast China, trending along the Solon Mountain-Hegenshan-Jarud Banner-Nenjiang-Heihe line, representing a post-orogenic paleo-sture zone [13,23]. The third viewpoint, based on integrated geophysical and geochemical evidence, suggests the existence of two independent blocks (Erguna–Xing’an and Songnen) during the Early Paleozoic that collided along the Heihe–Nenjiang–Baicheng belt in the Early Carboniferous [24]. The fourth identifies an Early Carboniferous (330–360 Ma) NE-trending magmatic arc extending from the Heihe–Nenjiang–Moguqi zone to southern Mongolia [15,25], based on Late Paleozoic magmatic records. These differing interpretations reflect ongoing research and debate regarding the tectonic evolution of Northeast China.
The formation epoch of the HHTB is primarily regarded as the Late Silurian–Devonian [1,26,27], the Late Devonian–Early Carboniferous [28], the Early Carboniferous [10,17,29,30], the Pre-Permian [31]. Conclusively, owing to the lack of temporal and spatial constraints of petrological evidence in the middle section of the Great Xing’an Range, it has given rise to diverse perceptions of the spatial extension and controversies regarding the formation chronology.
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Figure 1. Geological sketch map of the study area. (a) Simplified tectonic framework of Central Asia Orogenic Belt. (after [2]). (b) Simplified tectonic framework of NE China (after [15]). (c) Geological map of the Jalaid Banner area. (d) Geological map of the Ulanhot area.
Figure 1. Geological sketch map of the study area. (a) Simplified tectonic framework of Central Asia Orogenic Belt. (after [2]). (b) Simplified tectonic framework of NE China (after [15]). (c) Geological map of the Jalaid Banner area. (d) Geological map of the Ulanhot area.
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The 1:50,000 regional geological survey in the Ulanhot area within the middle section of the Great Xing’an Range has been conducted. The author dissected the formerly designated Early Permian Dashizhai Formation in this region and identified the Early Carboniferous volcanic rocks. This magmatic activity is a crucial subject for the investigation of the HHTB. In light of this, this paper undertakes a systematic examination of the petrography, zircon U-Pb isotopic chronology, and geochemistry of the Early Carboniferous volcanic rocks in the Ulanhot area. In conjunction with the regional geological setting, the magma source, petrogenesis, tectonic setting, and formation mechanism of these volcanic rocks have been studied, furnishing a geological foundation for the collage and evolutionary history of the Erguna–Xing’an Block and the Songnen Block.

2. Geological Setting and Sample Descriptions

2.1. Geological Setting

The study area is located in the Jalaid Banner–Ulanhot region within the central part of the Great Xing’an Range, and it is positioned in the basin-range transitional area between the Songliao Basin and the Great Xing’an Range. The HHTB forms a vital region for the amalgamation of the Erguna–Xing’an Block and the Songnen Block (Figure 1b). Within the study region, a substantial amount of Mesozoic volcanic rocks and granites, accompanied by a minor quantity of Paleozoic sedimentary strata and Paleozoic granites, are predominant [32]. Regarding the basement of the Xing’an Block, it is conventionally asserted that it encompasses a unified Precambrian metamorphic basement, as exemplified by the “Luomahu Group” and “Zalantun Group”, amongst others [33,34,35]. The preponderance of these has been decomposed into Paleozoic metamorphic rock series. Consequently, a growing multitude of scholars assert that it constitutes a Paleozoic accretionary terrane. The Songnen Block, also known as the Songnen–Zhangguangcai Range Block, essentially encompasses the Songliao Basin, the Lesser Khingan Mountains–Zhangguangcai Range, and a segment of the southern Great Xing’an Range. The strong covering makes it difficult to identify ancient rocks [36,37,38]. In recent years, a multitude of Precambrian geological entities have been successively unearthed in the Longjiang–Ulanhot area situated on the western edge of the Songnen Block [39,40,41]. These data suggest that the Songnen Block ought to possess an Early Precambrian basement.
In the Jalaid Banner, the exposed strata predominantly consist of Mesozoic volcanic-sedimentary formations, with a minor quantity of Early Carboniferous volcanic rocks being locally exposed (Figure 1c). The area of intrusive rocks is comparatively extensive and can be categorized into four phases: the Early Carboniferous, the Late Carboniferous, the Late Jurassic, and the Early Cretaceous. The Late Paleozoic intrusive rocks have been profoundly disrupted by the subsequent magmatic occurrences and overlaid by the Middle Cenozoic volcanoes or sedimentary substances. Regionally, these rock units typically occur as fragmented, discrete blocks exhibiting either fault-bounded contacts with surrounding geological bodies, or preservation within younger magmatic intrusions. The geological outcrops in Ulanhot exhibit a relatively straightforward configuration, with the stratigraphy primarily encompassing Early Carboniferous volcanic rocks, the sedimentary strata of the Middle Permian Zhesi Formation, and Mesozoic volcanic-sedimentary strata. The intrusive rocks are predominantly of Early Permian and Late Jurassic origin.

2.2. Sample Descriptions

In recent years, the author has carried out an elaborate field investigation and sample gathering of the Early Carboniferous volcanic rocks in the Jalaid Banner and Ulanhot regions. The volcanic activities of this era are respectively demarcated in the Jubaotun area in the northwestern part of Jalaid Banner, and in the Lingxia Town and Najin Town in the southern portion of Ulanhot. The rock varieties encompass andesite, schist, and rhyolitic tuff. This work collected representative samples in the above-mentioned areas, along with chronology and geochemical samples. The andesite (WJH-TW7) was collected from the Jubaotun area in the northwest of Jalaid Banner, with the latitude and longitude coordinates of N46°58′48″, E122°3′43″; the schist (D16015) was collected from the northwest of Lingxia Town, with the latitude and longitude coordinates of N45°54′4″, E122°17′42″; the rhyolitic tuff (D17038) was collected from the west of Najin Town, with the latitude and longitude coordinates of N45°47′21″, E122°4′58″.
Andesite (WJH-TW7), grayish-black, porphyritic texture, massive structure (Figure 2a,b). The phenocrysts are plagioclase, with a content of 1%, subhedral tabular, with a particle size of about 0.3–1 mm, first-order gray-white interference color, polysynthetic twins, and individual circle structures can be observed, with a relatively strong surface alteration. The matrix shows an interwoven structure, and the subhedral prismatic plagioclase is oriented. The matrix has been altered strongly, with chloritization and epidotization (Figure 2c).
Schist (D16015), presenting pale gray, exhibits a porphyroblastic texture and a schistose structure (Figure 2d,e). The residual porphyroblast constituents are as follows: Plagioclase, taking an augen shape, with a minor portion in the guise of lenses, minor twinning, mild undulatory extinction, and weak sericitization on the surface. The long axes are slightly oriented, with a grain size ranging from 0.1–0.2 mm and content of approximately 10 to 15%. The matrix component, mica, constitutes roughly 40%, with the components being muscovite and biotite, both manifesting as small and elongated flaky sheets and being distributed in an oriented manner around the residual porphyroblasts. The remainder consists of felsic components, presenting in the form of fine particles or cryptocrystalline. Quartz aggregates are discernible in the form of lenticular and intermittent strips and are all distributed in an oriented manner. The protolith is rhyolitic tuff (Figure 2f).
Rhyolitic tuff (D17038), grayish-white, tuffaceous texture, stratified structure (Figure 2g,h). The rock is predominantly constituted of light brown clay minerals and felsic cryptocrystalline constituents. The crystal fragments primarily consist of angular and subangular feldspar and quartz, with a grain size ranging from 0.03 to 0.1 mm, with a content of approximately 5%. Within the rock, irregularly distributed carbonate minerals are observed in banded and massive forms and fill along the fractures (Figure 2i).

3. Analytical Methods

3.1. Major and Trace Element Analyses

Geochemical analyses were performed on 14 samples at the Northeast China Supervision and Inspection Center of Mineral Resources (Ministry of Natural Resources, Shenyang). Analytical methods included petrographic examination followed by major element analysis using XRF (precision >2%) and trace/REE measurements using ICP-MS (Thermo X Series II). Sample preparation involved removing altered surfaces, crushing to 74 μm with an agate mill, and acid digestion with sequential heating and final dilution to 0.5% HNO3. Analytical precision ± 5% for elements >1 μg/g, 8% for <10 μg/g, and 10% for transition metals. Detailed analytical methods followed those described by Chen et al. [42]. All results are presented in Table 1.

3.2. Zircon LA–ICP–MS U-Pb Isotope Dating

Zircon U-Pb dating was conducted using LA–ICP–MS at the Tianjin Institute of Geology and Mineral Resources, employing an Agilent 7500a quadrupole ICP-MS equipped with a New Wave Research UP-193 solid-state laser system (193 nm wavelength). Analytical conditions included a 32 μm laser spot size operating at 10 J/cm2 energy density and 8 Hz repetition rate. Zircon 91,500 served as the primary reference material for U-Pb fractionation correction [43], while common lead was corrected using LA–ICP–MS Common Lead Correction (v3.15) based on Andersen’s method [44]. Data processing involved Glitter software (v4.0) for isotopic ratio and elemental concentration calculations, with age determinations and Concordia diagram generation performed using Isoplot/Ex 3.0 [45]. Final results are presented as weighted mean ages (95% confidence level) with 1σ analytical uncertainties on Concordia plots. All data are listed in Table 2.

3.3. Zircon Lu-Hf Isotope Dating

Zircon Lu-Hf isotopic analyses were conducted at the Tianjin Institute of Geology and Mineral Resources. In this procedure, a Thermo Fisher Neptune type Multi-Collector Inductively Coupled Plasma Mass Spectrometer (MC-ICPMS) and a 193 nm laser ablation system (NEWWAVE193nm FX) with a laser spot size of 5 μm (Thermo Fisher Scientific, Waltham, MA, USA) were employed. The methodologies are based on the techniques presented by Geng Jianzhen et al. [46]. The data are listed in Table 3.

4. Analytical Results

4.1. Zircon U–Pb Geochronology

The zircons within the andesite (WJH-TW7) sample exhibit euhedral to subhedral columnar or granular morphologies, with a size predominantly spanning from 70 to 130 μm, and possess distinct oscillatory growth zoning (Figure 3a). The Th/U ratios of the zircons fluctuate between 0.47 and 1.59, with an average of 0.77. These characteristics indicate a magmatic origin. A sum of 20 representative zircons was chosen for examination. Except for point 8, which markedly deviates from the Concordia curve due to evident Pb loss, the remaining test points lie on the Concordia curve. The age of zircon 206Pb/238U at point 16 is 410 ± 9 Ma, which might be captured zircon. The ages of zircon 206Pb/238U at the other 18 test points range from 331 Ma to 353 Ma, and the concordant weighted average age is 343.1 ± 3.8 Ma (MSWD = 0.69), corresponding to the middle of Early Carboniferous.
A total of 30 zircons were examined for the schist (D16015) sample. Amongst them, point 23 demonstrates Pb depletion, and the data deviates from the concordant curve. The remaining 29 points align with the concordant curve. The majority of zircon samples are columnar or granular, with a size spanning from 60 to 120 μm. A significant portion of them exhibits distinct magmatic oscillation rings (Figure 3b). The Th/U ratios of zircons fluctuate between 0.49 and 3.51 (with individual Th/U ratios of 0.08), with an average of 1.21. Certain zircons possess a core-rim structure, with the core being magmatic zircon and the rim being a metamorphic one. Point 14 is situated in the core of the zircon (magmatic zircon); the zircon is round-shaped, the boundary assumes a harbor-like configuration, and a minor metamorphic rim is developed. Its 207Pb/236U age is 1929.3 ± 39.4 Ma, and the Th/U value is 1.58, representing a magmatic event. Spots 6, 9, and 13 are located in the core of the zircons with a core-rim structure. The 206Pb/238U ages are 385.6 ± 7.1, 373.3 ± 8.3, and 390 ± 7.8, and the Th/U values range from 1.8 to 1.51, representing a magmatic event. All of the above zircons are captured zircons. The 206Pb/238U ages of other zircons range from 328 to 364 Ma, and the concordant weighted average age is 343.1 ± 3.7 Ma (MSWD = 2.0), which falls within the middle of Early Carboniferous. In conclusion, the diagenetic age of the rock is 343.1 ± 3.7 Ma, corresponding to the mid-early Carboniferous. After diagenesis, a metamorphic effect is evident, and zircons from the Middle-Late Devonian and Early Paleoproterozoic magmatic events are captured.
In the rhyolitic tuff (D17038) sample, the zircon grains possess a good crystalline form, presenting euhedral to subhedral columnar and granular morphologies, with a size predominantly spanning from 50 to 130 μm (Figure 3c). They exhibit distinct oscillatory zoning, and the Th/U ratios of zircons fluctuate between 0.29 and 1.52, with an average of 0.79. These characteristics indicate a magmatic origin. A total of 30 spots were subjected to analysis, among which spot 23 demonstrates Pb loss and deviates from the concordant curve, whereas the other 29 spots lie on or in proximity to the concordant curve. Six analyzed spots (2, 5, 8, 11, 14, 26) represent captured zircons. Spot 8 yields a 206Pb/238U age of 865 ± 25 Ma, while the other five spots display 207Pb/236U ages ranging from 1547 to 2453 Ma. The remaining 23 spots exhibit zircon 206Pb/238U ages ranging from 339 Ma to 358 Ma, with a concordant weighted average age of 347.4 ± 3.0 Ma (MSWD = 0.64), falling within the Early Carboniferous.

4.2. Major and Trace Element Geochemistry

The SiO2 content of the andesite samples spans from 51.69%–60.09wt%, attaining a mean value of 57.57wt%, thereby falling within the category of intermediate rocks. The Al2O3 content varies between 17.75wt% and 21.14wt%, with an average of 19.11%. The total alkali content (Na2O + K2O) ranges from 6.77wt% to 8.17wt%, averaging at 7.43wt%. The TiO2 content fluctuates from 0.91wt% to 1.5wt%, with a mean value of 0.99%. The MgO content varies from 1.35wt% to 1.62%, with an average of 1.49wt%. The P2O5 content ranges from 0.31wt% to 0.38wt%, averaging at 0.34wt%. The Mg# value extends from 26.35 to 38.53, with an average of 32.37. On the Zr/TiO2-Nb/Y diagram (Figure 4a), the samples are positioned within the andesite/basalt fields and subalkaline basalt, respectively. In the K2O-SiO2 diagram (Figure 4b), the rocks pertain mainly to the high-K calc-alkaline series and, secondarily, to the calc-alkaline series. The aluminum saturation index (A/CNK) fluctuates between 1.01 and 1.17, with an average of 1.07, belonging to the weakly peraluminous series. The total rare earth element content (ΣREE) of the andesite is 72.2–15.71 ug/g. The ratio of light rare earth elements (LREEs) to heavy rare earth elements (HREEs) varies from 6.13 to 7.94, with an average of 6.78. The REE distribution pattern is right-skewed (Figure 5a), exhibiting significant fractionation between LREEs and HREEs. The (La/Yb)N ranges from 5.72 to 1.89, indicating a relative abundance of LREEs and a relative scarcity of HREEs. The weak negative Eu anomaly, with δEu ranging from 0.87 to 0.95, might be associated with the fractional crystallization of plagioclase. In the primitive mantle-normalized trace element spider diagram (Figure 5b), the andesites are enriched in large ion lithophile elements (LILEs) such as Rb, K, and Ba and depleted in elements such as Nb, Ta, Ti, and Hf.
The schist and the rhyolitic tuff exhibit relatively analogous geochemical features. The SiO2 content spans from 66.2wt% to 71.37wt%, with an average of 68.41wt%, thereby belonging to the felsic rock. The Al2O3 content fluctuates between 12.41wt% and 15.49wt%, with an average of 14.38wt%. The total alkali content (Na2O + K2O) demonstrates a broad range of variation, ranging from 3.77wt% to 6.5wt%, with an average of 5.48wt%. The TiO2 content is comparatively low, ranging from 0.5wt% to 0.76wt%, with an average of 0.58wt%. The CaO content varies from 0.54wt% to 1.54wt%, with the CaO content of individual specimens reaching 4.8wt%. The MgO content ranges from 1.31wt% to 2.33wt%, with an average of 1.64wt%. The P2O5 content fluctuates between 0.11wt% and 0.19wt%, with an average of 0.13wt%, and the Mg# value varies from 35.92 to 48.7, with an average of 42.89. In the Zr/TiO2-Nb/Y diagram (Figure 4a), the samples are situated within the range of dacite and rhyolite. In the K2O-SiO2 diagram (Figure 4b), the rock pertains to the high-potassium calc-alkaline rock series, while individual points fall within the calc-alkaline series. The content of ΣREE is 121.32–23.31 μg/g, and the ratio of LREEs/HREEs is 6.18–8.52, with an average of 7.2. The REE distribution curve is right-inclined (Figure 5a), and the fractionation between LREEs and HREEs is conspicuous, with (La/Yb)N being 5.32–8.19. The LREEs are relatively enriched, while the HREEs are relatively depleted, featuring a weak negative Eu anomaly, with δEu ranging from 0.62 to 0.8, which might be associated with the fractional crystallization of plagioclase. In the primitive mantle-normalized trace element spider diagram (Figure 5b), the rock samples are enriched in LILEs such as Rb, K, Ba, etc., and are depleted in elements such as Nb, Ta, Ti, Sr, P, etc.

4.3. Zircon Hf Isotope

In situ micro-area Hf isotope analysis of the Early Carboniferous volcanic rocks in the Ulanhot area was carried out (Table 3, Figure 6). For the andesite (WJH-TW7), the initial 176Hf/177Hf ratios of the 12 magmatic zircons, which denote the diagenetic age, fluctuate within the range of 0.282205 to 0.282827. The εHf(t) values span from −13 to 9.4, the one-stage model ages extend from 597 to 1540 Ma, and the two-stage model ages range from 697 to 1937 Ma. Regarding the schist (D16015), the initial 176Hf/177Hf ratios of the 11 magmatic zircons representing the diagenetic age vary within the interval of 0.282211 to 0.282858. The εHf(t) values range from −12.8 to 10, the one-stage model ages fluctuate between 582 and 1523 Ma, and the two-stage model ages fall within the range of 710 to 2158 Ma. Concerning the rhyolitic tuff (D17038), the initial 176Hf/177Hf ratios of the 12 magmatic zircons indicate the diagenetic age oscillate within the bounds of 0.282433 and 0.282777. The εHf(t) values extend from −4.7 to 7.3, the one-stage model ages fluctuate from 693 to 1168 Ma, and the two-stage model ages lie within the scope of 884 to 1647 Ma.

5. Discussion

5.1. The Geochronological Significance of Volcanic Rocks from Ulanhot Area

This study undertakes zircon U-Pb isotope analyses on the volcanic rocks of the erstwhile mapped Early Permian Dashizhai Formation in the Jalaid Banner and Ulanhot regions. The results reveal that the zircon U-Pb ages of the diagenetic ages of volcanic rock are 343.1 ± 3.8 Ma, 343.1 ± 3.7 Ma, and 347.4 ± 3.0 Ma, respectively, which belong to the Early Carboniferous. The Dashizhai Formation is primarily disseminated to the north of the Xar Moron tectonic belt and to the south of the HHTB. The rock assemblage predominantly consists of a suite of intermediate–basic to felsic volcanic rocks and sedimentary rocks, forming in the Early Permian [52]. Owing to the minor strata with volcanic rocks attributed to the Permian in the central and southern sectors of the Great Xing’an Range, the volcanic rocks exposed during this era are frequently incorporated into the Dashizhai Formation, engendering numerous complications and misunderstandings in subsequent applications [53]. Predecessors have carried out a large number of chronological studies on the volcanic strata of the Dashizhai Formation in different regions. However, the volcanic rocks show a large age span, mainly concentrated in the Early Permian, Early Silurian, and Late Carboniferous [52,53,54,55]. The Dashizhai Formation is of great significance for the study of the geological history, the division of the tectonic framework, and the exploration of mineral resources in this area. Therefore, we propose that the Dashizhai Formation, which was mainly divided according to petrography in the past, should be disintegrated to redefine the temporal and spatial distribution of volcanic-sedimentary strata.
Currently, numerous reports have been presented on the Early Carboniferous intrusive rocks in the Central Great Xing’an Range; however, the reports concerning the Early Carboniferous volcanic rocks are comparatively scarce. Wang et al. [56] recognized the Early Carboniferous intermediate–basic intrusive rocks associated with subduction in the Jalaid Banner area. Zhao et al. [14,29] respectively identified the volcanic and intrusive rocks related to subduction in the Hadayang Town, Wuerqihan area, and Yinhe area. Combined with the identification of Early Carboniferous volcanic rocks in this study, it indicates that the magmatic activity in the Early Carboniferous is very frequent, and most of them have the characteristics of arc magmatic rocks, which can form a magmatic arc [15].

5.2. Petrogenesis and Tectonic Setting

The lithogeochemical data indicate that the andesites in the Jalaid Banner region possess a relatively moderate SiO2 content, low MgO content, Mg#, and compatible element Cr (with an average of 26.6 ug/g), Ni (with an average of 2.7 ug/g). The above data significantly deviate from the composition range of the original mantle magma [57], indicating that its genesis has no direct correlation with the primary mantle melt. The key elemental ratios (Nb/Ta = 10.6–23.97) exhibit transitional characteristics between mid-ocean ridge basalt (MORB, Nb/Ta ≈ 17.55) and continental crust (Nb/Ta ≈11–12) [58], and the Th/Ta ratio of the andesites varies from 2.81 to 11.68, surpassing the Th/Ta ratio of the primitive mantle (which is 3.4) [58], combining with the high P2O5 contents (0.31%–0.38%), showing the characteristics of crust–mantle admixture.
The Hf isotope composition of zircon further confirms this mechanism: the εHf(t) values exhibit a bimodal distribution (−13–9.4), negative end-member (TDM2 = 1410–1937 Ma), and age of Precambrian fragments within the Xingmeng Orogenic Belt (e.g., 1.8 Ga–2.5 Ga magmatic activity in the Longjiang–Ulanhot area) [39,40,41] were of consistent age, indicating that the recycled continental crust material carried by subducting plates or the detachment of micro landmasses were involved in partial melting [59]. The positive end-member (TDM2 = 697–1253 Ma) reflects the juvenile crust of the Phanerozoic era (possibly due to the contribution of sub arc crustal melting or plate melting) [7]. High Ba/Th (143~687), low Th/Nb (0.26~0.82), and significant Nb, Ti negative anomalies (Figure 5b) are consistent with the typical characteristics of plate dehydration releasing Ba-rich fluids to metasomatize mantle wedges [60,61].
The flat HREE patterns (Gd/Yb ≈ 2–3) indicate magma generation within the spinel stability field (depth < 80 km), as spinel exhibits weak fractionation of HREEs, resulting in relatively flat HREE distributions in the melt [62]. The elevated Dy/Yb ratios (1.9–2.8) typically suggest the coexistence of garnet and spinel in the source region (transitional zone at depths of ~60–80 km) [63]. The negative Eu anomalies (δEu = 0.87–0.95) in the rocks and the negative P2O5-SiO2 correlation indicate that plagioclase and apatite fractional crystallization dominated the late-stage magmatic evolution [64]. The subdued negative Eu anomalies may result from limited plagioclase fractionation or redistribution of Eu by coexisting minerals (e.g., apatite, K-feldspar). In the Sr/Y-Y diagram (Figure 7a) and the (La/Yb)N-YbN diagram (Figure 7b), the samples are situated within the domain of conventional island arc rocks, and both the Sr/Y and Y magnitudes are rather low, signifying a mixing source [65]. In the trace element spider diagram, Nb and Ti exhibit conspicuous negative anomalies, which can be construed as typical indicators of magmatic activity in the subduction zone [60].
In summary, the Early Carboniferous andesites from the Ulanhot region were not derived from direct melting of the primitive mantle but rather represent products of multistage mixing and interaction between crustal and mantle materials in a subduction zone setting [66]. The magmatic source involved both components from fluid-metasomatized mantle wedge melting and contributions from melts derived from ancient continental crust (e.g., delaminated microcontinental fragments or recycled sediments) as well as Phanerozoic juvenile crust. During magma ascent and evolution, these melts further underwent late-stage differentiation dominated by plagioclase and apatite fractional crystallization. These integrated evidence not only reveals the complex crust–mantle dynamics during the Early Carboniferous in the Xing’an-Mongolia Orogenic Belt but also provides critical geochemical constraints for understanding the magmatic-tectonic evolution during the final closure stage of the Paleo–Asian Ocean domain.
Felsic volcanic rocks possess a relatively elevated SiO2 content (with an average of 68.41wt%), a considerable Na2O + K2O content (averaging 5.48wt%), a relatively low MgO content (averaging 1.64wt%), and a rather low TiO2 content (averaging 0.58wt%), exhibiting the same characteristics as the continental crust [67]. Furthermore, these rocks are enriched in LREEs and LILEs (such as Rb, K, Ba) yet depleted in HREE and HFSEs (such as Nb, Ta, Ti, Sr, P), implying that they are derived from the crust. The rocks predominantly consist of calc-alkaline and high-potassium calc-alkaline rocks (Figure 4b), exhibiting either I-type or S-type granites. The felsic volcanic rocks possess relatively elevated Zr + Nb + Ce + Y values and (Na2O + K2O)/CaO values and diminished TFeO/MgO values. In the rock type discrimination diagrams, they all lie within the I-type and S-type granites areas (Figure 8). Nevertheless, the typical aluminous minerals of S-type granite, such as corundum, tourmaline, and garnet, are not discernible in the mineral composition. The P2O5 content of the felsic volcanic rocks is comparably low, spanning from 0.11% to 0.19%, whereas the P2O5 content of S-type granites typically exceeds 0.2% [68,69]. Therefore, the felsic volcanic rocks in the study area are I-type granites rather than S-type granites.
The felsic volcanic rocks within the study area possess a comparatively elevated A/CNK ratio, yet their Zr/Hf ratio ranges from 32.77 to 58.1, falling within the spectrum of highly fractionated granites (25–55) [70], suggesting their affiliation with highly fractionated granites. The extant research on the magmatic process of fractionated granites intimates that the cause for the variance in the geochemical characteristics of this sort of fractionated granite is the fractional crystallization of feldspar throughout the evolution of the granite magma, which results in a reduction of the CaO content within the rocks [71]. The εHf(t) values of the two felsic volcanic rock samples fluctuate within the ranges of −12.8 to 10 and −4.7 to 7.3, respectively. Concurrently, the two-stage model ages span from 582 to 1523 Ma and 884 to 1647 Ma, exhibiting a considerable variation spectrum. This implies that the magma originates from the partial melting of the freshly accreted crust and Middle Proterozoic crustal substances. Furthermore, the felsic volcanic rocks possess a relatively low Sr/Y ratio and a relatively elevated Y content, featuring classic island arc rock characteristics (Figure 7). This indicates that the magma could not have been generated in the stable region of the garnet mineral phase (≥10 kPa). Commonly, within this region, adakitic magma is formed as a result of the partial melting of the oceanic subduction slab or of the thickened lower crust [65,72,73]. The felsic volcanic rocks in the study area might have been formed in the crustal portion above the stable region of the garnet mineral phase. In summary, the magma of the felsic volcanic rocks in the study area derives from the partial melting of shallower crustal materials.
Minerals 15 00610 g008
Figure 8. (a) (Na2O+K2O)/CaO versus (Zr + Nb + Ce + Y) diagram [74], (b) TFeO/MgO versus (Zr + Nb + Ce + Y) diagram [74] for the volcanic rocks from the Ulanhot area. A: A-type granites; FG: Fractionated granites; OGT: unfractionated granites.
Figure 8. (a) (Na2O+K2O)/CaO versus (Zr + Nb + Ce + Y) diagram [74], (b) TFeO/MgO versus (Zr + Nb + Ce + Y) diagram [74] for the volcanic rocks from the Ulanhot area. A: A-type granites; FG: Fractionated granites; OGT: unfractionated granites.
Minerals 15 00610 g008
The volcanic rocks within the study area primarily encompass andesite, schist (with the protolith being rhyolitic tuff), and rhyolitic tuff. Certain rocks exhibit pronounced schistosity and carbonatization. Generally, high-field-strength incompatible elements such as Th, Hf, Ta, and Nb are not readily influenced by the subsequent metamorphism and can be employed to discern the tectonic milieu of volcanic rocks. The volcanic rocks exhibit a relatively low TiO2 content (with an average of 0.73%), a comparatively high Al2O3 content (with an average of 16.7%) as well as K2O content (with an average of 3.9%). They are enriched in LILEs such as Rb, K, and Ba, while being depleted in HFSEs like Nb, Ta, Ti, and Hf, which suggest that the protoliths of these rocks possess the characteristics of arc volcanic rocks and form in an island arc or active continental margin environment. The comparatively elevated La/Nb ratio (ranging from 1.91 to 3.3) further accentuates the features of subduction-related arc volcanic rocks. In the Hf/3-Th-Nb/16 diagram, all the andesite samples are encompassed within the island arc calc-alkaline basalts area (Figure 9a). In the Th/Yb-Nb/Yb diagram, all the projections are positioned in the continental arc region (Figure 9b). In the Rb-(Y + Nb) diagram, all the felsic volcanic rock samples are located within the volcanic arc area (Figure 9c). In conclusion, we contend that the Early Carboniferous volcanic rocks in the Ulanhot area are the products of subduction in an active continental margin.

5.3. Geological Significance

The HHTB is the final collage position between the Erguna–Xing’an Block and the Songnen Block [8,15,20,23,78]. As previously stated, there remain substantial controversies concerning its precise extensional position and era. The Early Carboniferous volcanic rocks under investigation in this study are situated in the Ulanhot region within the middle portion of the HHTB. The zircon U-Pb age spans from 343 to 347 Ma, corresponding to the middle Early Carboniferous. The tectonic setting pertains to the active continental margin, and its genesis is intimately associated with the evolution of the HHTB. In recent years, a considerable number of magmatic occurrences with a subduction tectonic setting have been documented in the vicinity of the study area. For instance, Wang et al. [56] discerned the Early Carboniferous gabbros and diorites in the Jalaid Banner region, which were engendered in an active continental margin setting associated with subduction, analogous to an island arc tectonic setting. Yang et al. [79] disclosed Early Carboniferous high-Mg andesites in the Xing’an Reservoir area of Ulanhot beneath a subduction zone, intimating the presence of a suite of Early Carboniferous magmatic arcs trending toward the northeast in the Jalaid Banner–Ulanhot area. Regionally, there are also numerous reports of Early Carboniferous magmatic rocks. For example, Early Carboniferous gabbro associated with subduction in the Moguqi area [15], I-type and differentiated I-type granite formed by island arc magmatic activities in the Late Devonian–Early Carboniferous subduction setting in the Zalantun area [9], andesite showing the characteristics of intraplate ocean island basalt of the Late Devonian Daminshan Formation and intermediate-felsic volcanic rocks with the features of arc volcanic rocks in the Zalantun area [80], as well as Late Devonian–Early Carboniferous I-type granite exposed in Yargenchu in the southwestern Zalantun [81]. These magmatic activities are presumably linked to the HHTB, suggesting that a continuous subduction process transpired between the Erguna–Xing’an Block and the Songnen Block during the Late Devonian–Early Carboniferous. The age of the Hegenshan ophiolite in the southern part of the HHTB has been found by some scholars to be no later than the Early Carboniferous [82,83]. The age of the Duobaoshan ophiolitic mélange, remnants of the Nenjiang ophiolitic mélange, and arc magmatic rocks in the northern section of Great Xing’an Range is primarily the Late Devonian–Early Carboniferous [14,84]. Consequently, the aforementioned evidence suggests that a continuous subduction process transpired between the Erguna–Xing’an Block and the Songnen Block throughout the Late Devonian to Early Carboniferous period, accompanied by intense arc magmatism. The suture zone stretches from the Heihe–Nenjiang–Zalantun region to the Jalaid Banner–Ulanhot area. The discovery of S-type granite in the middle Early Carboniferous (334 Ma) in the Jalaid Banner area [10] and the identification of magmatic activities in the late Early Carboniferous (322 Ma) within the late-orogenic to post-orogenic extensional tectonic setting in the Quanshenglinchang area [85] suggests that the HHTB was already undergoing collisional orogeny during the middle and late Early Carboniferous. In conclusion, the Early Carboniferous volcanic rocks in the Ulanhot region are likely to have originated in a subduction setting before the collision between the Erguna–Xing’an Block and the Songnen Block. The HHTB might be spatially distributed along the Heihe–Nenjiang–Moguqi–Jalaid Banner–Ulanhot–Hegenshan–Erenhot zone.

6. Conclusions

(1)
The LA–ICP–MS zircon U-Pb dating results show that the crystallization ages of the andesite, the schist, and the rhyolitic tuff originally assigned to the Dashizhai Formation in the Ulanhot area are 343.1 ± 3.8 Ma, 343.1 ± 3.7 Ma, and 347.4 ± 3.0 Ma, respectively, and their formation period is the Early Carboniferous.
(2)
In the study area, the Early Carboniferous andesites are the products of the amalgamation of crustal and mantle substances in the vicinity of the subduction zone, and a certain degree of crystal fractionation has occurred. The felsic volcanic rocks originate from the partial melting of shallower crustal materials. Both are formed in the volcanic arc environment of the active continental margin.
(3)
The central Greater Xing’an Range gave rise to an Early Carboniferous magmatic arc, which emerged within the subduction setting before the collision and amalgamation of the Erguna–Xing’an Block and the Songnen Block.

Author Contributions

Methodology, Y.Z.; investigation, Y.Z., T.Q., C.Q., C.Z., J.C. and W.S.; data curation, Y.Z.; writing—original draft, Y.Z. and T.Q.; writing—review and editing, Y.Z. and T.Q. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the China Geological Survey (Grants DD20240208202), Natural Science Foundation of Liaoning Province (NO. 2024-MSLH-498) and the funding project of Northeast Geological S&T Innovation Center of China Geological Survey (NO. QCJJ2024-07).

Data Availability Statement

The authors confirm that the data generated or analyzed during this study are provided in full within the published article.

Conflicts of Interest

The authors declare no conflicts of interest.

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Minerals 15 00610 g002
Figure 2. Field outcrops and micrographs of the Early Carboniferous volcanic rocks from the Ulanhot region; (ac): WJH-TW7 andesite; (df): D16015 schist; (gi): D17038 rhyolitic tuff; Pl: plagioclase; Qz: quartz; Bi: biotite.
Figure 2. Field outcrops and micrographs of the Early Carboniferous volcanic rocks from the Ulanhot region; (ac): WJH-TW7 andesite; (df): D16015 schist; (gi): D17038 rhyolitic tuff; Pl: plagioclase; Qz: quartz; Bi: biotite.
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Minerals 15 00610 g003
Figure 3. Cathodoluminescence (CL) image and zircon U-Pb age concordant diagrams of the volcanic rocks in the Ulanhot area.
Figure 3. Cathodoluminescence (CL) image and zircon U-Pb age concordant diagrams of the volcanic rocks in the Ulanhot area.
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Minerals 15 00610 g004
Figure 4. Classification and series diagrams of the volcanic rocks in the Ulanhot area. (a) Zr/TiO2 versus Nb/Y (after [47]), (b) K2O versus SiO2 (after [48]).
Figure 4. Classification and series diagrams of the volcanic rocks in the Ulanhot area. (a) Zr/TiO2 versus Nb/Y (after [47]), (b) K2O versus SiO2 (after [48]).
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Minerals 15 00610 g005
Figure 5. Chondrite-normalized REE patterns (a) (normalizing values after [49]) and primitive mantle-normalized trace element spider diagrams (b) (normalizing values after [50]) for the volcanic rocks from the Ulanhot area.
Figure 5. Chondrite-normalized REE patterns (a) (normalizing values after [49]) and primitive mantle-normalized trace element spider diagrams (b) (normalizing values after [50]) for the volcanic rocks from the Ulanhot area.
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Minerals 15 00610 g006
Figure 6. εHf(t) versus Zircon ages diagram (a,b) of the volcanic rocks from the Ulanhot area. (Fields for the Central Asian Orogenic Belt and North China Craton are from [51]).
Figure 6. εHf(t) versus Zircon ages diagram (a,b) of the volcanic rocks from the Ulanhot area. (Fields for the Central Asian Orogenic Belt and North China Craton are from [51]).
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Minerals 15 00610 g007
Figure 7. (a) Sr/Y versus Y diagram [65], (b) Y versus Rb diagram [65] for the volcanic rocks from the Ulanhot area.
Figure 7. (a) Sr/Y versus Y diagram [65], (b) Y versus Rb diagram [65] for the volcanic rocks from the Ulanhot area.
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Minerals 15 00610 g009
Figure 9. Identification diagram of the tectonic setting for the volcanic rocks from the Ulanhot region. (a) Hf/3-Th-Nb/16 diagram (after [75]); (b) Th/Yb-Nb/Yb diagram (after [76]); (c) Rb-(Y + Nb) diagram (after [77]).
Figure 9. Identification diagram of the tectonic setting for the volcanic rocks from the Ulanhot region. (a) Hf/3-Th-Nb/16 diagram (after [75]); (b) Th/Yb-Nb/Yb diagram (after [76]); (c) Rb-(Y + Nb) diagram (after [77]).
Minerals 15 00610 g009
Table 1. Major element (wt.%), rare element, and trace element (ppm) composition of volcanic rocks in Ulanhot area.
Table 1. Major element (wt.%), rare element, and trace element (ppm) composition of volcanic rocks in Ulanhot area.
LithologyAndesite (WJH-TW7)Schist (D16015)Rhyolitic Tuff (D17038)
Sample No.-YQ1-YQ2-YQ3-YQ4-YQ5-YQ1-YQ2-YQ3-YQ4-YQ1-YQ2-YQ3-YQ4-YQ5
SiO256.2560.0451.6959.8060.0966.268.3371.3766.8070.2768.4968.6767.9967.55
Al2O319.4717.7821.1419.3917.7513.2315.4612.4113.9913.7714.8414.9515.3115.49
Fe2O32.742.223.261.923.161.602.663.603.620.961.341.481.401.62
FeO3.953.865.622.342.742.092.021.662.072.382.702.492.432.56
CaO3.663.414.014.914.244.080.540.591.041.541.040.890.940.90
MgO1.411.551.621.351.511.731.312.202.331.451.491.481.331.45
Na2O4.904.094.614.173.902.830.0200.0711.073.873.363.383.563.35
K2O3.273.192.923.222.872.094.913.703.631.812.772.902.943.03
P2O50.340.310.380.360.330.140.180.130.190.120.110.110.110.12
TiO20.990.911.111.050.910.500.660.560.760.520.550.540.560.58
MnO0.070.060.080.040.050.0780.0290.0960.100.100.080.080.080.09
LOI2.542.323.491.592.525.573.323.733.993.242.972.832.973.23
SUM99.5999.7399.92100.12100.07100.1399.44100.1399.60100.0499.7499.8099.6199.96
La12.6911.4714.1312.5819.4324.426.822.535.829.5430.9428.5332.1331.83
Ce28.8826.3132.0427.6941.2950.457.946.681.262.1566.1359.4268.7268.55
Pr3.613.354.173.474.985.856.855.639.247.377.787.148.088.08
Nd16.2315.1518.7815.3522.0722.727.423.138.027.9029.5825.7730.3330.77
Sm3.733.514.303.264.845.026.055.288.945.246.025.476.096.26
Eu1.040.941.150.941.281.231.371.311.881.161.151.091.141.18
Gd3.222.963.582.673.914.205.224.687.624.264.834.614.745.03
Tb0.460.430.510.380.550.700.860.751.260.650.800.750.750.84
Dy3.042.853.282.483.633.995.064.457.454.275.214.914.985.49
Ho0.530.480.550.430.560.841.020.891.500.780.970.940.931.02
Er1.541.391.601.241.542.242.872.454.122.422.872.802.853.03
Tm0.210.180.210.160.190.440.540.470.780.360.410.420.410.43
Yb1.591.421.641.221.282.583.332.774.832.593.233.183.053.28
Lu0.200.180.200.150.160.390.480.440.690.330.390.370.370.37
Y15.7814.6816.5212.8816.6120.525.421.836.122.9927.4226.0826.3929.38
Ba685.69594.79502.321100765.92583771613610358.69620.00669.03727.58738.48
Cr25.0327.1927.0027.0024.0624.446.076.951.813.9617.1817.7116.6618.88
Ga19.7918.7422.8619.7820.6316.522.517.522.415.4418.1918.6318.3019.52
Nb5.836.025.766.046.959.8812.89.2111.810.6511.7511.6112.1511.94
Rb77.7979.0890.7371.2274.7972.416813213766.5092.7697.1898.03100.27
Sr335.68273.76301.80369.62323.5433763.660.9139253.43243.67233.35259.94252.15
Zr119.58112.60128.44104.56126.45192214162213210.89216.52221.63223.37228.54
Li32.8631.6748.4722.4328.0429.122.855.462.031.2631.9230.9128.4032.55
Be2.201.902.402.012.011.552.402.562.921.852.512.642.682.81
Sc24.5123.6828.6126.4621.819.2510.912.919.811.4812.6012.6713.0313.27
Ni19.2320.6423.9518.5021.2017.312.532.423.29.038.688.999.539.98
U0.650.550.620.420.591.682.001.992.461.661.851.761.882.02
Hf2.051.642.101.321.343.314.264.206.504.124.745.014.784.97
Ta0.410.410.280.570.290.590.710.620.990.630.610.610.560.48
Th4.792.602.821.602.275.145.465.087.527.538.939.559.309.78
ΣREE76.9770.6286.1472.02105.71124.98145.75121.32203.31149.01160.29145.40164.57166.17
δEu0.900.870.870.950.870.800.730.790.680.730.630.650.630.62
(La/Yb)N5.725.796.187.4010.896.785.775.835.328.196.886.447.556.95
Table 2. LA–ICP–MS zircon U-Pb dating data of volcanic rocks from the Ulanhot area.
Table 2. LA–ICP–MS zircon U-Pb dating data of volcanic rocks from the Ulanhot area.
Sample No.PbThUTh/UIsotopic RatiosAges (Ma)
μg/gμg/gμg/g207Pb/206Pb 207Pb/235U206Pb/238U207Pb/206Pb207Pb/235U206Pb/238U
RatioRatioRatioAgesAgesAges
Andesite (WJH-TW7)
1443842421.590.05350.00200.40270.01760.05440.001535087344133429
2951930.550.05470.00290.40300.02200.05420.0015398123344163409
31061940.640.05120.00230.36880.01680.05260.0013256102319123318
411641040.610.05570.00290.42280.02310.05440.0011443115358173427
5362033900.520.05170.00150.38040.01120.05340.00112726932783357
6231412200.640.05260.00250.40120.02060.05530.00193091013421534711
7271422960.480.05270.00370.40910.02800.05600.0014322159348203519
85931090.850.07270.01780.18730.04200.02020.00051006513174361293
9654065950.680.05270.00130.40560.00980.05610.00113175434673527
10463302641.250.05580.00180.43000.01430.05630.001244375363103537
11271682590.650.05370.00180.40490.01360.05530.001236774345103478
12402413660.660.05500.00150.41300.01300.05480.00134096335193448
13634590.580.05610.00350.40280.02190.05530.00184541323441634711
14191341341.000.06170.00270.45760.02060.05360.001366393383143368
15632680.470.05640.00330.42370.02380.05600.00164781313591735110
16251281840.690.05480.00190.49220.01680.06570.001646780406114109
17231391970.700.05460.00210.41040.01600.05430.001339885349113418
18513324400.750.05360.00160.39710.01300.05400.00143546934093399
19282061641.260.05500.00190.41820.01620.05530.001540978355123479
20372342880.810.05570.00170.41210.01510.05350.001244369350113368
Schist (D16015)
12014973231.540.05280.00090.38990.00730.05360.00073203933453364
2551291151.120.05190.00120.38470.01020.05370.00082805633083375
31012302510.920.05350.00100.39860.00870.05400.00073503134163395
4631411271.110.05220.00130.39690.01120.05510.00093007533983466
5651441810.800.05270.00100.40320.01100.05540.00113174434483487
6733156010331.510.05340.00070.45440.01030.06160.00123463338073867
72041490.850.05520.00250.42480.02330.05570.0014420106359173508
8851852620.710.05250.00100.39480.01270.05450.00143063133893429
91122241891.190.05380.00120.44250.01230.05960.00143656437293738
10751631750.930.05400.00130.40220.01220.05400.00133695634393398
111272832351.200.05290.00110.39520.01000.05420.00123244433873407
121042241601.400.05400.00110.42050.01100.05650.00143694435683548
13891481371.080.05330.00130.45880.01290.06240.00133435638393908
1418373471.580.11820.00275.44380.21990.33320.0093192939189235185445
151132571791.430.05230.00130.38710.01100.05360.00102985633283376
161836740.490.05350.00180.39230.01500.05310.001235478336113347
171443382621.290.05260.00100.38250.00960.05270.00103094432973316
1820263520.080.05290.00100.38170.00930.05230.00103282532873286
19531111670.660.05330.00130.41340.01370.05620.001534364351103539
204028655741.510.05370.00090.41980.01060.05670.00133673335683558
211232782361.180.05360.00100.40610.01070.05490.00113544434683457
22941902700.700.05360.00100.42390.01260.05730.00133544435993598
23992201521.450.06030.00340.44920.04060.05340.00196171193772833512
241663623121.160.05240.00100.39790.00930.05500.00103062534073456
253547813981.960.05380.00080.42300.00900.05690.00103653335863576
262144973231.540.05310.00080.39580.00770.05400.00083453333963395
272374953881.280.05360.00080.42980.00930.05810.00113543336373647
2846411893393.510.05470.00090.40960.00950.05420.00084673934973415
291472983180.940.05340.00090.42810.01520.05820.0019343533621136411
301443152571.230.05280.00090.40380.00920.05550.00103203934473486
Rhyolitic tuff (D17038)
11543504640.750.05310.00080.41490.01020.05670.00133323335273558
2146671130.590.09680.00133.77830.09740.28290.0063156525158821160632
31764483901.150.05290.00090.39720.01070.05440.00123282534083417
4641471431.030.05400.00130.42130.01560.05660.0018369503571135511
56412522870.880.11320.00125.50320.14510.35230.008818543190123194642
6611451570.930.05350.00130.42020.01210.05690.00123505635693577
7611461001.470.05340.00140.41240.01480.05600.001534661351113519
882691620.430.06640.00111.31490.04230.14350.0044820338521986525
91042274500.500.05280.00090.41500.01500.05690.0018320533521135711
103997641.520.05400.00210.41060.01650.05520.001437283349123469
11126601140.530.09600.00163.29180.19170.24810.0127154732147945142966
12911973210.610.05340.00110.42030.01330.05710.0018346443561035811
13891992720.730.05350.00100.41690.01710.05650.0021350313541235413
144971302620.500.15480.00199.90330.34980.46370.0153240018242633245668
15611401510.930.05220.00130.40830.01530.05670.0019295693481135611
163497987481.070.05530.00090.41700.00810.05470.00104333935463436
171463304130.800.05340.00090.41820.01230.05680.00143465335593569
181122593960.650.05450.00090.41110.01030.05470.001039113635073446
19711652380.690.05330.00120.40220.01240.05470.00123436434393438
20531211730.700.05410.00140.42080.01420.05640.001437642357103549
21581271590.800.05410.00120.41770.01300.05590.00133765035493518
221513394720.720.05400.00100.41550.00830.05580.00093723135363505
23991274350.290.06790.00440.71560.11000.07320.00718661365486545543
241744163031.370.05350.00080.39810.00900.05400.00113503334073397
25701492460.600.05390.00100.41260.01050.05550.00103655835183486
264731331800.740.15980.00199.87590.30910.44790.0118245322242329238653
27871943020.640.05420.00090.40870.01100.05470.00103893934883436
281723856280.610.05360.00080.41110.01020.05560.00113673935073497
2936801150.690.05460.00160.40620.01260.05400.00103946734693396
3039871090.800.05390.00180.40820.01520.05490.000936972348113446
Table 3. Zircon Hf isotopic data for the volcanic rocks from the Ulanhot area.
Table 3. Zircon Hf isotopic data for the volcanic rocks from the Ulanhot area.
Sample No.Age
(Ma)		176Yb
177Hf		176Lu
177Hf		176Hf
177Hf		εHf(0)εHf(t)TDM1TDM2fLu/Hf
Andesite (WJH-TW7)
WJH-TW7-013420.0943750.0037800.2824760.000146−10.3−3.70.00004111791423−0.89
WJH-TW7-023400.0668190.0027040.2822050.001034−19.9−13.00.00004515401937−0.92
WJH-TW7-033310.0489050.0024500.2825340.000603−8.3−1.30.00004210521293−0.93
WJH-TW7-043420.0290980.0012870.2824670.000273−10.7−3.40.00004211141410−0.96
WJH-TW7-053350.0142100.0006070.2824970.000379−9.6−2.20.00002810521342−0.98
WJH-TW7-063470.0199260.0008640.2825440.000113−7.9−0.60.0000239931253−0.97
WJH-TW7-073510.0241540.0010430.2828270.0002772.19.40.000036597697−0.97
WJH-TW7-113530.0682330.0028000.2824600.000731−10.9−4.00.00004111711442−0.92
WJH-TW7-093520.0331800.0014160.2825490.000704−7.7−0.50.00003410001250−0.96
WJH-TW7-123440.0443280.0019890.2825840.000061−6.50.60.0000259661189−0.94
WJH-TW7-133470.0213660.0009420.2827120.000302−2.05.30.000029759924−0.97
WJH-TW7-143360.0364880.0016800.2826560.000394−4.03.20.0000278551044−0.95
Schist (D16015)
D16015-03339.000.0281590.0009560.2822890.000012−17.1−9.80.00001513581967−0.97
D16015-02337.000.0646050.0022150.2826700.000030−3.63.50.0000188511129−0.93
D16015-04346.000.0381700.0013300.2824850.000020−10.2−2.90.00001710951534−0.96
D16015-07350.000.0424420.0014310.2825250.000017−8.7−1.50.00001810401444−0.96
D16015-08342.000.0427950.0014730.2823920.000011−13.4−6.20.00001412301743−0.96
D16015-10339.000.0768290.0025100.2828580.0000193.010.00.000021582710−0.92
D16015-16334.000.0695940.0024080.2824640.000021−10.9−3.90.00001611581597−0.93
D16015-17331.000.0528200.0018340.2823310.000070−15.6−8.50.00001613291884−0.94
D16015-20355.000.0583800.0019330.2824850.000020−10.2−3.00.00001711121541−0.94
D16015-24345.000.0837580.0028680.2824100.000042−12.8−5.90.00001812511722−0.91
D16015-25357.000.0751940.0023980.2822110.000040−19.8−12.80.00001515232158−0.93
Rhyolitic tuff (D17038)
D17038-01355.000.0798510.0024270.2826680.000036−3.73.40.0000198601135−0.93
D17038-03341.000.0422400.0013410.2824330.000013−12.0−4.70.00002611681647−0.96
D17038-12358.000.0543410.0017570.2826700.000006−3.63.70.0000178411120−0.95
D17038-17356.000.0806400.0025830.2826220.000083−5.31.70.0000219311241−0.92
D17038-19343.000.0683150.0021180.2826310.000036−5.02.20.0000189071215−0.94
D17038-20354.000.0481080.0015580.2827260.000016−1.65.70.000018756991−0.95
D17038-25348.000.0318630.0010140.2826240.000010−5.22.20.0000168891213−0.97
D17038-27343.000.0494140.0017800.2825550.000021−7.7−0.50.00001810081381−0.95
D17038-29339.000.0498630.0019000.2827340.000045−1.35.90.000023752979−0.94
D17038-30344.000.0675150.0020920.2827770.0000250.27.30.000019693884−0.94
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Zang, Y.; Qin, T.; Qian, C.; Zhang, C.; Chen, J.; Sun, W. Geochronology, Geochemistry, and Tectonic Significance of Early Carboniferous Volcanic Rocks from the Ulanhot Region in the Central Great Xing’an Range. Minerals 2025, 15, 610. https://doi.org/10.3390/min15060610

AMA Style

Zang Y, Qin T, Qian C, Zhang C, Chen J, Sun W. Geochronology, Geochemistry, and Tectonic Significance of Early Carboniferous Volcanic Rocks from the Ulanhot Region in the Central Great Xing’an Range. Minerals. 2025; 15(6):610. https://doi.org/10.3390/min15060610

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Zang, Yanqing, Tao Qin, Cheng Qian, Chao Zhang, Jingsheng Chen, and Wei Sun. 2025. "Geochronology, Geochemistry, and Tectonic Significance of Early Carboniferous Volcanic Rocks from the Ulanhot Region in the Central Great Xing’an Range" Minerals 15, no. 6: 610. https://doi.org/10.3390/min15060610

APA Style

Zang, Y., Qin, T., Qian, C., Zhang, C., Chen, J., & Sun, W. (2025). Geochronology, Geochemistry, and Tectonic Significance of Early Carboniferous Volcanic Rocks from the Ulanhot Region in the Central Great Xing’an Range. Minerals, 15(6), 610. https://doi.org/10.3390/min15060610

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