Late Devonian–early Permian accretionary orogenesis along the North Tianshan in the southern Central Asian Orogenic Belt

Li, Chao; Xiao, Wenjiao; Han, Chunming; Zhou, Kefa; Zhang, Jien; Zhang, Zhixin

doi:10.1080/00206814.2014.913268

Cited by 49 publications

(36 citation statements)

References 155 publications

(165 reference statements)

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“…The complex marks the final collision between the CTB in the south and the Junggar terrane in the north (Gao et al, 1997;Windley et al, 2007;Xiao et al, 2008;Zhu et al, 2009;An et al, 2013;Li et al, 2015). However, the timing of final subduction between CTB and Junggar terrane remains unclear.…”

Section: Geodynamic Implications For the Central Asian Orogenic Beltmentioning

confidence: 99%

“…However, Han et al (2010) proposed that the collision occurred before the Late Carboniferous according to the presence of the Sikeshu 'stitching pluton' within the North Tianshan accretionary complex. Recently, Li et al (2015) considered that the subduction of the Junggar Ocean (a branch of the paleo-Asian Ocean) probably continued into the early Permian. Therefore, the accreted igneous rocks that it contains, such as the early Carboniferous Bayingou ophiolitic rocks of this study can shed new light on the evolution history of the North Tianshan accretionary complex.…”

Section: Geodynamic Implications For the Central Asian Orogenic Beltmentioning

confidence: 99%

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Accreted seamounts in North Tianshan, NW China: Implications for the evolution of the Central Asian Orogenic Belt

Yang

Kerr

et al. 2018

Journal of Asian Earth Sciences

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A B S T R A C T The Carboniferous Bayingou ophiolitic mélange is exposed in the North Tianshan accretionary complex in the southwestern part of the Central Asian Orogenic Belt (CAOB). The mélange is mainly composed of serpentinised ultramafic rocks (including harzburgite, lherzolite, pyroxenite, dunite and peridotite), pillowed and massive basalts, layered gabbros, radiolarian cherts, pelagic limestones, breccias and tuffs, and displays blockin-matrix structures. The blocks of ultramafic rocks, gabbros, basalts, cherts, and limestones are set in a matrix of serpentinised ultramafic rocks, massive basalts and tuffs. The basaltic rocks in the mélange show significant geochemical heterogeneity, and two compositional groups, one ocean island basalt-like, and the other mid-ocean ridge-like, can be distinguished on the basis of their isotopic compositions and immobile trace element contents (such as light rare earth element enrichment in the former, but depletion in the latter). The more-enriched basaltic rocks are interpreted as remnants/fragments of seamounts, derived from a deep mantle reservoir with low degrees (2-3%) of garnet lherzolite mantle melting. The depleted basalts most likely formed by melting of a shallower spinel lherzolite mantle source with ∼15% partial melting. It is probable that both groups owe their origin to melting of a mixture between plume and depleted MORB mantle. The results from this study, when integrated with previous work, indicate that the Junggar Ocean crust (comprising a significant number of seamounts) was likely to have been subducted southward beneath the Yili-Central Tianshan block in the Late Devonian-Early Carboniferous. The seamounts were scraped-off and accreted along with the oceanic crust in an accretionary wedge to form the Bayingou ophiolitic mélange. We present a model for the tectonomagmatic evolution of this portion of the CAOB involving prolonged intra-oceanic subduction with seamount accretion

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Section: Geodynamic Implications For the Central Asian Orogenic Beltmentioning

confidence: 99%

Section: Geodynamic Implications For the Central Asian Orogenic Beltmentioning

confidence: 99%

Accreted seamounts in North Tianshan, NW China: Implications for the evolution of the Central Asian Orogenic Belt

Yang

Kerr

et al. 2018

Journal of Asian Earth Sciences

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“…). This part of the NTAC represents a late Paleozoic continental arc that is composed mainly of late Carboniferous volcanosedimentary rocks and ophiolitic slices that formed during subduction of the Paleo–Junggar oceanic crust (Li et al ., ). The Precambrian metamorphic basement rocks of the NTAC consist of Precambrian (821–798 Ma) granitic gneiss, biotite–plagioclase gneiss, monzonite granulite, fine‐grained amphibolite, migmatite, quartzite, marble, and schists of the Wenquan Formation (exposed in Wenquan, south of Sayram Lake and Nalati; Chen et al ., ).…”

Section: Regional Geological Settingmentioning

confidence: 97%

Cu–Mo Differential Mineralization Mechanism of the Dabate Polymetallic Deposit in Western Tianshan, NW China: Evidence from Geology, Fluid Inclusions, and Oxygen Isotope Systematics

et al. 2019

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Classic porphyry Cu–Mo deposits are mostly characterized by close temporal and spatial relationships between Cu and Mo mineralization. The northern Dabate Cu–Mo deposit is a newly discovered porphyry Cu–Mo polymetallic deposit in western Tianshan, northwest China. The Cu mineralization postdates the Mo mineralization and is located in shallower levels in the deposit, which is different from most classic porphyry Cu–Mo deposits. Detailed field investigations, together with microthermometry, laser Raman spectroscopy, and O‐isotope studies of fluid inclusions, were conducted to investigate the origin and evolution of ore‐forming fluids from the main Mo to main Cu stage of mineralization in the deposit. The results show that the ore‐forming fluids of the main Mo stage belonged to an NaCl + H2O system of medium to high temperatures (280–310°C) and low salinities (2–4 wt% NaCl equivalent (eq.)), whereas that of the main Cu stage belonged to an F‐rich NaCl + CO2 + H2O system of medium to high temperatures (230–260°C) and medium to low salinities (4–10 wt% NaCl eq.). The δ18O values of the ore‐forming fluids decrease from 3.7–7.8‰ in the main Mo stage to −7.5 to −2.9‰ in the main Cu stage. These data indicate that the separation of Cu and Mo was closely related to a large‐scale vapor–brine separation of the early ore‐forming fluids, which produced the Mo‐bearing and Cu‐bearing fluids. Subsequently, the relatively reducing (CH4‐rich) Mo‐bearing, ore‐forming fluids, dominantly of magmatic origin, caused mineralization in the rhyolite porphyry due to fluid boiling, whereas the relatively oxidizing (CO2‐rich) Cu‐bearing, ore‐forming fluids mixed with meteoric water and precipitated chalcopyrite within the crushed zone at the contact between rhyolite porphyry and wall rock. We suggest that the separation of Cu and Mo in the deposit may be attributed to differences in the chemical properties of Cu and Mo, large‐scale vapor–brine separation of early ore‐forming fluids, and changes in oxygen fugacity.

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“…The ophiolite consists of serpentinized peridotite, gabbro, diabase, basalt, plagiogranite, and siliceous‐pelagic sedimentary rocks, which are in fault contact with the surrounding turbidites (Wang et al, ). The ophiolites were formed in the Early Carboniferous, as dated by SHRIMP zircon U–Pb methods on plagiogranite and gabbro in the Bayingou ophiolite (325 and 344 Ma; Xu, Li, et al, ; Xu, Xia, et al, ) and plagiogranite from the Kuitunhe ophiolite of (SIMS zircon U–Pb age of 343 Ma; Li et al, ).…”

Section: Geological Setting and Samplingmentioning

confidence: 99%

“…The petrology, geochemistry, and geochronology of ophiolites and related volcanic‐arc and post‐collisional rocks have been studied to reconstruct the evolutionary history of the NTO (An, Zhu, Wei, & Lai, ; Han et al, ; Li et al, ; Long et al, ; Wang, Shu, Cluzel, Faure, & Charvet, ; Wang et al, ; Xu, Li, et al, ; Xu, Xia, et al, ). Although the exact closure time is still debated, it is widely accepted that the subduction of NTO continued at least to the Late Carboniferous (Han et al, ; Li et al, ; Wang et al, ; Wang et al, ; Xiao et al, ). However, the subduction process, especially the time‐span of the NTO is still a puzzle due to limited geochronological data.…”

Section: Introductionmentioning

confidence: 99%

Detrital zircon U–Pb–Hf isotopes study of the Lower Carboniferous Anjihai Formation from the northern margin of the Yili Block, NW China

et al. 2018

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The North Tianshan Accretionary Complex represents a Late Palaeozoic suture between the Junggar Terrane and the Yili Block. We report detrital zircon U–Pb dating and Hf isotope results for a sandstone from the Lower Carboniferous Anjihai Formation in the northern margin of the Yili Block, to reveal the geochronological framework of the northern Yili Block, and discuss the subduction process of the North Tianshan Ocean (NTO). The detrital zircon ages were divided into 2 clusters, namely, the Precambrian and Palaeozoic ones. The Palaeozoic age group can be further divided into 3 subgroups, that is, 472–461 Ma, 448–423 Ma, and 406–335 Ma, with peaks at 465, 436, and 346 Ma, respectively. All the Palaeozoic zircons have oscillatory zoning textures and high Th/U ratios, showing an igneous provenance. The zircon Ti‐temperatures are between 584 and 809 °C, suggesting that their source rocks were I‐ or S‐type granitic rocks. In addition, most of the Palaeozoic zircons have positive εHf(t) values, indicating that the source rocks of the Palaeozoic zircons are derived from not only Mesoproterozoic continental crust but also involved depleted mantle components, which matched well with the Hf isotopic signatures of magmatic rocks from the northern Yili Block. Based on the regional geology, these zircons were thought to be sourced from magmatic rocks that were related to the subduction of the NTO. Taking into consideration the Middle–Late Ordovician arc‐type granitoids in the Wenquan area, we conclude that the northern margin of the Yili Block was a unified active continental margin in the Palaeozoic, and the subduction of the NTO started at least from the Middle Ordovician.

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Late Devonian–early Permian accretionary orogenesis along the North Tianshan in the southern Central Asian Orogenic Belt

Cited by 49 publications

References 155 publications

Accreted seamounts in North Tianshan, NW China: Implications for the evolution of the Central Asian Orogenic Belt

Accreted seamounts in North Tianshan, NW China: Implications for the evolution of the Central Asian Orogenic Belt

Cu–Mo Differential Mineralization Mechanism of the Dabate Polymetallic Deposit in Western Tianshan, NW China: Evidence from Geology, Fluid Inclusions, and Oxygen Isotope Systematics

Detrital zircon U–Pb–Hf isotopes study of the Lower Carboniferous Anjihai Formation from the northern margin of the Yili Block, NW China

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