Geochemistry and petrogenesis of the early Palaeozoic appinite-granite complex in the Western Kunlun Orogenic Belt, NW China: implications for Palaeozoic tectonic evolution

Zhu, Jie; Li, Qiugen; Chen, Xu; Tang, Hao-Shu; Wang, Zongqi; Chen, Yanjing; Liu, Shuwen; Xiao, Bing; Chen, Junlu

doi:10.1017/s0016756817000450

Cited by 19 publications

(8 citation statements)

References 71 publications

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“…La/Yb‐based crustal thickness estimates show episodic crustal thickening and thinning processes, which were divided into four cycles (I to IV). These crustal thickening and thinning events are supported by accompanying geological evidences including A‐type or bimodal rocks (~523 Ma Taxkorgan rocks, ~478 Ma Kusilafu pluton and ~405 Ma North Kudi pluton; Gao et al, 2013; Li et al, 2019; Xiao et al, 2005; Yuan et al, 2002), adakitic rocks (~513 Ma Datongdong and Yirba plutons, 470–452 Ma Datong and Akedala plutons and 430 Ma Buya pluton; Hu, Guo, et al, 2017; Li et al, 2019; Liao et al, 2010; Liu et al, 2014; Wang et al, 2017; Xu et al, 2021; Ye et al, 2008; Yin et al, 2020; Zhu et al, 2018), ~520 Ma northward migration of arc magmatism (Yin et al, 2020) and ~440 Ma amphibolite‐facies metamorphism (Zhang, Zou, et al, 2019). Crustal thickness estimates from magmatic zircons are in agreement with those from the whole‐rock La/Yb method.…”

Section: Resultsmentioning

confidence: 99%

“…Admittedly, Cycle III accretionary orogenesis in West Kunlun could be a rather local event. Co-existence of subducted oceanic crust-and thick lower crust-derived adakites (e.g.Datong pluton;Li et al, 2019;Liao et al, 2010;Wang et al, 2017;Zhu et al, 2018) together with a sharp shift in zircon Hf isotopic compositions toward positive values at 460 Ma are somewhat consistent with the subduction of oceanic ridges or slab breakoff, which deserves further study.5 | IMPLIC ATIONSSignificant accretionary orogeneses at 520-450 Ma were identified before the 450-400 Ma collisional orogenesis in Proto-Tethyan West Kunlun. In West Kunlun, 520-480 Ma accretionary orogenesiswas a geodynamical response to the final collision among blocks within Gondwana.…”

mentioning

confidence: 87%

“…Key magmatic rocks are specially marked. These rocks were compiled from (Cui et al, 2006; Cui, Wang, Bian, Zhu, et al, 2007; Cui, Wang, Bian, Luo, et al, 2007; Gao et al, 2013; Hu, 2018; Hu et al, 2016; Hu, Wang, et al, 2017; Hu, Guo, et al, 2017; Jia et al, 2013; Li et al, 2019; Liao et al, 2010; Liu et al, 2014, 2016, 2019; Wang et al, 2013, 2017; Xiao et al, 2005; Xu et al, 2021; Ye et al, 2008; Yin et al, 2020; Yuan et al, 2002; Zhang et al, 2007; Zhang, He, et al, 2016; Zhang, Liu, et al, 2016; Zhang et al, 2018a; Zhang, Wu, Chen, et al, 2019; Zhang, Wu, Li, et al, 2019; Zheng et al, 2013; Zhu et al, 2016, 2018; Zhuan et al, 2018). Please see Table S2 for more details.…”

Section: Geological Settingmentioning

confidence: 99%

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Accretionary orogenesis triggered by collision across continent distance: Evidence from the Proto‐Tethyan West Kunlun, China

et al. 2023

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Proto‐Tethyan orogenic processes prior to the late Ordovician collision remain unclear. Both whole‐rock La/Yb‐ and zircon Eu/Eu*‐based crustal thickness proxies along with petrological and geological observations were used to reconstruct mountain‐building history for the West Kunlun orogenic belt, China, over the span of Early Palaeozoic. Here, we demonstrate that Proto‐Tethyan West Kunlun crust has observed significant accretionary orogeneses at 520–480 Ma and 480–450 Ma and collisional orogenesis at 450–400 Ma. The 520–480 Ma accretionary orogenesis in West Kunlun together with the coeval Delamerian accretionary contractional orogenesis in eastern Australia were simultaneously induced by continent‐continent collisions that welded the Gondwana landmass. Ca. 440 Ma docking of Tarim and its eastern neighbouring blocks along the northern margin of Gondwana in turn triggered the Lachlan accretionary orogenesis along the opposite margin. This study highlights that accretionary orogenesis could be a manifestation of far‐field compressional stress from continent‐continent collision.

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Section: Resultsmentioning

confidence: 99%

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confidence: 87%

Section: Geological Settingmentioning

confidence: 99%

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Accretionary orogenesis triggered by collision across continent distance: Evidence from the Proto‐Tethyan West Kunlun, China

et al. 2023

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“…Our geochronological study reveals that the sediments were mainly derived from Karakul‐Mazar and Bashgumbaz magmatic arcs, and older zircons were derived from the Central and South Pamir terranes, which are mainly composed of metamorphosed Palaeozoic–Triassic passive margin rocks (Rutte et al, 2017; Schwab et al, 2004). However, we do not exclude the possible derivation of detritus material from the Kunlun Terrane, which is composed of composite igneous rocks of Palaeozoic–Mesozoic age (Jiang et al, 2013; Xiao, Windley, Chen, Zhang, & Li, 2002; Zhang et al, 2016; Zhu et al, 2018) that were marked by several episodes of calcic to calc‐alkaline magmatism ranging in age from 260 to 240, 290 to 260, and 450 to 420 Ma (Cowgill, Yin, Harrison, & Xiao‐Feng, 2003; Harris, Ronghua, Lewis, Hawkesworth, & Yuquan, 1988; Zhang et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

Late Palaeozoic to Late Triassic northward accretion and incorporation of seamounts along the northern South Pamir: Insights from the anatomy of the Pshart accretionary complex

et al. 2020

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Late Palaeozoic-Mesozoic volcano-sedimentary rocks within the Rushan-Pshart Suture zone in the Pamir contain critical information on the subduction-accretion history of the Rushan-Pshart Ocean (Meso-Tethys) prior to the Central-South Pamir collision. In this article, we report new field, petrographic, geochronological, and geochemical data of the Permian to Triassic basic volcanic and sedimentary rocks from the Pshart area. Our field study unravels block-in-matrix components within some sedimentary mélanges, which, together with some previously defined ophiolitic mélanges, enables us to define the Pshart accretionary complex (AC), and thus for the first time to discuss the subduction-accretion history of the Rushan-Pshart Ocean and the growth of the Pshart AC. The youngest detrital U-Pb zircons suggest that deposition of sediments was in the Late Triassic (212 Ma). Detritus of Triassic age was primarily derived from the Triassic Karakul-Mazar Arc-AC (Northern Pamir) and the Bashgumbaz Magmatic Arc, which developed along the northern margin of South Pamir. The evidence of north-directed thrusts along the Kara Djilga-2 and Ken Djilga transverses confirms previous interpretations of southward subduction of the Rushan-Pshart oceanic lithosphere beneath the South Pamir. Geochemical OIB-type data of the Pshart alkaline basaltic rocks suggest formation in seamounts incorporated into the Pshart AC during the southward subduction of the Rushan-Pshart Ocean. The youngest Late Triassic deposition age is consistent with the coeval time of closure of the Palaeo-Tethys and Meso-Tethys oceans in the Pamir. The Pshart AC formed by subduction-accretion processes during the southward subduction of the Meso-Tethys Ocean along the northern South Pamir and the final docking of the Central and South Pamir (Cimmerian Blocks) may have occurred after the Late Triassic.

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“…High Sr/Y magmatic rocks usually have adakitic signatures (high Sr and low Y and Yb concentrations with high Sr/Y and La/Yb ratios), which are related to continental crustal evolution and recycling, specific geodynamics and porphyry-type Cu ± Mo ± Au deposits (Xu et al 2002;Martin et al 2005;Castillo, 2012). Meanwhile, high Ba-Sr intrusions usually vary from appinite to granite and are characterized by high alkali, Ba-Sr and light rare earth element (LREE) concentrations and low heavy REE (HREE) concentrations, carrying important information on their petrogenesis and geodynamics in orogenic belts or subduction zones (Tarney & Jones, 1994;Fowler et al 2008;Bruand et al 2014;Pan et al 2016;Zhu et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Petrogenesis of high Ba–Sr plutons with high Sr/Y ratios in an intracontinental setting: evidence from Early Cretaceous Fushan monzonites, central North China Craton

Huang

et al. 2019

Geol. Mag.

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Geochronological, major and trace element, and Sr–Nd–Hf isotopic data are reported for the monzonitic rocks of the Fushan pluton in the Taihang Mountains, central North China Craton, in order to investigate their sources, petrogenesis and tectonic implications. Zircon U–Pb dating results reveal that the Fushan pluton was emplaced during the Early Cretaceous (∼126–124 Ma). The monzonites and quartz monzonites are mainly characterized by calc-alkaline and magnesian features and display light rare earth element (LREE) enrichment and flat heavy REE (HREE) patterns with slightly positive Eu anomalies. They have similar whole-rock initial 87Sr/86Sr ratios (0.70653–0.70819), εNd(t) values (−13.6 to −18.6) and zircon εHf(t) values (−21.8 to −17.3). The primary magma of the Fushan pluton was derived from the partial melting of a spinel-facies amphibole-bearing ancient enriched lithospheric mantle. The monzonitic rocks also have high Ba–Sr and low Y and Yb contents, with high Sr/Y and La/Yb ratios. These geochemical features of monzonitic rocks are not only inherited from the magma source but also significantly enhanced by crystal fractionation during magmatic evolution; e.g. hornblende fractionation increased the Ba–Sr concentrations and Sr/Y ratios. During the Early Cretaceous, the slab sinking and roll-back of the Palaeo-Pacific Plate could have created an ancient big mantle wedge beneath East Asia and induced a lithospheric extensional process in the central North China Craton within an intracontinental setting.

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Geochemistry and petrogenesis of the early Palaeozoic appinite-granite complex in the Western Kunlun Orogenic Belt, NW China: implications for Palaeozoic tectonic evolution

Cited by 19 publications

References 71 publications

Accretionary orogenesis triggered by collision across continent distance: Evidence from the Proto‐Tethyan West Kunlun, China

Accretionary orogenesis triggered by collision across continent distance: Evidence from the Proto‐Tethyan West Kunlun, China

Late Palaeozoic to Late Triassic northward accretion and incorporation of seamounts along the northern South Pamir: Insights from the anatomy of the Pshart accretionary complex

Petrogenesis of high Ba–Sr plutons with high Sr/Y ratios in an intracontinental setting: evidence from Early Cretaceous Fushan monzonites, central North China Craton

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