Zircon U–Pb geochronology and geochemistry of Devonian plagiogranites in the Kuerti area of southern Chinese Altay, northwest China: Petrogenesis and tectonic evolution of late Paleozoic ophiolites

Shen, Xiaoming; Zhang, Haixiang; Wang, Qiang; Saha, Abhishek; Ma, Lin

doi:10.1002/gj.3020

Cited by 10 publications

(18 citation statements)

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“…The Shiquanhe plagiogranite samples are characterized with enriched LREEs, flat HREEs and negative Eu anomalies with Eu/Eu* ratios varying from 0.38 to 0.75 (Figure 6a). The primitive mantle normalization of trace elements of the plagiogranite samples exhibits selective depletion of large‐ion lithophile elements (LILEs) such as Ba and Sr and high‐field‐strength elements (HFSEs) such as Nb, Ta, and Ti, which is consistent with those of typical plagiogranites and different from those of continental granites (Figure 6b; Rollinson, 2009; Shen et al, 2017). The negative Eu and Sr anomalies may be related to the fractionation of plagioclase.…”

Section: Resultsmentioning

confidence: 64%

“…In the plot of K 2 O versus SiO 2 , all the samples can be grouped as low K 2 O series and fall into the oceanic plagiogranite field, which are different from that of continental granites (Figure 5c; Maniar & Piccoli, 1989; Yarmolyuk et al, 2016; Yang et al, 2017). Moreover, in the ternary plot the samples plot in the trondhjemite and tonalite fields and show less orthoclase character as typical oceanic plagiogranites, which distinguish the Shiquanhe plagiogranite from continental granites (Figure 5d; Coleman & Peterman, 1975; Shen et al, 2017; Xu et al, 2017; Wu et al, 2018).…”

Section: Resultsmentioning

confidence: 99%

“…(a) Chondrite‐normalized REE patterns and (b) primitive mantle‐normalized trace element spidergrams of the Shiquanhe plagiogranite. Data sources: fractionation‐type from Freund et al (2014); shear‐type from Shen et al (2017); subduction‐type from Li and Li (2003a); obduction‐type from Whitehead, Dunning, and Spray (2000); data for the Lagkorco plagiogranite are from Xu et al (2018); the chondrite and primitive mantle normalizing data are from Sun and McDonough (1989) [Colour figure can be viewed at wileyonlinelibrary.com]…”

Section: Resultsmentioning

confidence: 99%

“…Plagiogranite in the study area occurs as lenticular bodies within the metabasite of the Shiquanhe ophiolite, and its length and width are almost 6 m and 5 m, respectively (Figure 2a,b). Metabasite surrounding the plagiogranite features stretching lineation and develops ocellar structure (Figure 2c,d), suggesting metamorphism due to shear deformation (Shen et al, 2017). In addition, a chilled margin is not observed between the plagiogranite and metabasite (Figure 2c).…”

Section: Field Observation and Petrographymentioning

confidence: 99%

“…Although seldom found and a silicic signature which differs from the ultramafic‐mafic rocks in oceanic crust, plagiogranite can provide crucial information for studying the origin and evolution of oceanic lithosphere (Grimes, Ushikubo, John, & Valley, 2011; Rollinson, 2014; Haase et al, 2016; Furnes & Dilek, 2017 and references there in). But the remarkable thing is that plagiogranite can be generated at different stages of oceanic crust evolution (Koepke, Berndt, Feig, & Holtz, 2007) and its genesis can be attributed to five models as follows: (1) extreme fractional crystallization of basaltic magma in oceanic crust (Freund, Haase, Keith, Beier, & Garbe‐Schönberg, 2014); (2) partial melting of shear metamorphosed mafic rocks in the shear zone of the lower oceanic crust third layer during the oceanic crust migration process (Pedersen & Malpas, 1984; Shen, Zhang, Wang, Saha, & Ma, 2017; Xu, Li, Fan, Wang, & Xie, 2018); (3) dehydration melting products of subducted oceanic crust under high pressure conditions (Yoshikawa & Ozawa, 2007); (4) anatexis of sedimentary rocks beneath ophiolite thrust fragments during the obduction of ophiolite onto the continental crust (Skjerlie, Pedersen, Wennberg, & De La Rosa, 2000); and (5) immiscibility products of felsic and iron‐rich basaltic magmas under anhydrous conditions (Dixon & Rutherford, 1979).…”

Section: Introductionmentioning

confidence: 99%

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An island arc origin of Jurassic plagiogranite in the Shiquanhe ophiolite, western Bangong Suture, Tibet: Zircon U–Pb chronology, geochemistry, and tectonic implications of Bangong Meso‐Tethys

Liu

Nayak

et al. 2021

Geological Journal

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The plagiogranites in ophiolites are minor in volume but can provide crucial information for the origin and tectonic evolution of ancient oceanic lithosphere. This paper presents the geochronology and geochemistry of a newly discovered plagiogranite in the Shiquanhe ophiolite, from the west end of the Shiquanhe‐Jiali ophiolite sub‐belt, Bangong Suture, central Tibet. Zircon U–Pb dating of two samples yields Middle Jurassic ages (167.4 ± 1.2 Ma and 167.5 ± 1.5 Ma). The plagiogranite has positive whole‐rock εNd(t) (4.2–4.9) and zircon εHf(t) (9.6–14.3) values, high Th/Nb ratios (0.6–2.8) but relatively low La/Nb ratios (0.9–9.9), indicating that it was possibly derived from a depleted mantle with the contribution of minor subducted sediments. The LREE‐enrichment but HREE‐flat patterns with negative Eu anomalies and negative Nb‐Ti anomalies resemble those of shear‐type plagiogranites, which mean that this rock was likely formed by partial melting of metabasite. Combined with the plagiogranite which does not exhibit chilled contacts against the Shiquanhe ophiolitic metabasite, suggests that the plagiogranite may have been derived from the associated ophiolitic metabasite. Geochemical calculating and modelling indicate that the plagiogranite was possibly produced by a low degree (<10%) partial melting of metabasite and replenished by minor sediments melts at low temperature (<800 °C) and low pressure (<0.1 GPa) conditions. The Shiquanhe plagiogranite, together with the contemporaneous Lagkorco plagiogranite in the same ophiolite sub‐belt, indicates that an intra‐oceanic island arc system was developed in the Bangong Meso‐Tethys during the Middle Jurassic.

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Section: Resultsmentioning

confidence: 64%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Field Observation and Petrographymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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An island arc origin of Jurassic plagiogranite in the Shiquanhe ophiolite, western Bangong Suture, Tibet: Zircon U–Pb chronology, geochemistry, and tectonic implications of Bangong Meso‐Tethys

Liu

Nayak

et al. 2021

Geological Journal

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Ore‐forming mafic plutons emplaced at syn‐collisional compressive setting in Kalatongke Ni–Cu sulphide district, Southern Altay, CAOB: New evidence from the Late Carboniferous granitic porphyries

Wang

Zhang

et al. 2021

Geological Journal

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The Kalatongke deposit is the largest Ni–Cu sulphide deposit in the Central Asian Orogenic Belt (CAOB) in northern Xinjiang. The tectonic setting of the Kalatongke deposit and the collision period of the Altai and East Junggar terranes remain controversial. This study involves petrological, geochemical, and geochronological evaluations of granitic porphyries in the Kalatongke. The granitic porphyries are divided into three types according to the characteristics of petrology and geochemistry, dated at ~339, ~325, and ~310 Ma. Type‐1 granitic porphyry exhibits evident syn‐collisional characteristics, with plagioclase phenocrysts extending in one direction. This type is metaluminous (A/CNK <1.1), characterized by low SiO2 and K2O contents, and depleted in Nb, Ta, P, and Ti. Type‐2 granitic porphyry is strongly peraluminous (A/CNK >1.1) and characterized by high SiO2 and Al2O3 but low Sr contents. Type‐3 granitic porphyry is also metaluminous (A/CNK <1.1) and has high SiO2 and K2O contents. The estimated crustal thickness of the Kalatongke area increased from 40 to 55 km from 339 to 310 Ma, thereby indicating that its existence within the collisional orogeny period. According to the estimated emplacement depth of the granitic and mafic intrusions, the crust had been thickening since then. During the late collision period, lithospheric detachment caused by terrane collision resulted in asthenospheric mantle upwelling and formed regional mafic intrusions along the Irtysh fault.

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Accretionary processes and metallogenesis of the Central Asian Orogenic Belt: Advances and perspectives

Xiao

Song

Windley

et al. 2020

Sci. China Earth Sci.

112

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As one of the largest Phanerozoic orogens in the world, the Central Asian Orogenic Belt (CAOB) is a natural laboratory for studies of continental dynamics and metallogenesis. This paper summarizes the research progresses of the accretionary processes and metallogenesis of the CAOB since the People's Republic of China was founded, and puts forward the prospect for future research. During the early period (1950s-1970s), several geological theories were applied to explain the geological evolution of Central Asia. In the early period of China's reform and opening-up, the plate tectonics theory was applied to explain the evolution of the northern Xinjiang and Xingmeng regions, and the opinion of subduction-collision between Siberian, Kazakhstan, and China-North Korea-Tarim plates was proposed. The idea of the Solonker-Yanbian suture zone was established. In the 1990s, the study of the CAOB entered a period of rapid development. One school of scholars including geologists from the former Soviet Union proposed a multi-block collision model for the assemblage of the CAOB. In contrast, another school of scholars, led by a Turkish geologist, Celal Şengör, proposed that the Altaids was formed through the growth and strike-slip duplicates of a single island arc, and pointed out that the Altaids is a special type of collisional orogen. During this period, Chinese geologists carried out a lot of pioneering researches on ophiolites and high-pressure metamorphic rocks in northern China, and confirmed the main suture zones accordingly. In 1999, the concept of "Central Asian metallogenic domain" was proposed, and it became one of the three major metallogenic domains in the world. Since the 21st century, given the importance for understanding continental accretion and metallogenic mechanism, the CAOB has become the international academic forefront. China has laid out a series of scientific research projects in Central Asia. A large number of important scientific research achievements have been spawned, including the tectonic attribution of micro-continents, timing and tectonic settings of ophiolites, magmatic arcs, identification and anatomy of accretionary wedges, regional metamorphism-deformation, (ultra)high-pressure metamorphism, ridge subduction, plume-plate interaction, archipelagic paleogeography and spatio-temporal framework of multiple accretionary orogeny, continental growth, accretionary metallogenesis, structural superposition and transformation, etc. These achievements have made important international influences. There still exist the following aspects that need further study: (1) Early evolution history and subduction initiation of the Paleo-Asian Ocean; (2) The accretionary mechanism of the extroversion Paleo-Asian Ocean; (3) The properties of the mantle of the Paleo-Asian Ocean and their spatiotemporal distribution; (4) The interaction between the Paleo-Asian Ocean and the Tethys Ocean; (5) Phanerozoic continental growth mechanism and its global comparison; (6) Accretionary metallogenic mechanism of the Central Asi...

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Zircon U–Pb geochronology and geochemistry of Devonian plagiogranites in the Kuerti area of southern Chinese Altay, northwest China: Petrogenesis and tectonic evolution of late Paleozoic ophiolites

Cited by 10 publications

References 119 publications

An island arc origin of Jurassic plagiogranite in the Shiquanhe ophiolite, western Bangong Suture, Tibet: Zircon U–Pb chronology, geochemistry, and tectonic implications of Bangong Meso‐Tethys

An island arc origin of Jurassic plagiogranite in the Shiquanhe ophiolite, western Bangong Suture, Tibet: Zircon U–Pb chronology, geochemistry, and tectonic implications of Bangong Meso‐Tethys

Ore‐forming mafic plutons emplaced at syn‐collisional compressive setting in Kalatongke Ni–Cu sulphide district, Southern Altay, CAOB: New evidence from the Late Carboniferous granitic porphyries

Accretionary processes and metallogenesis of the Central Asian Orogenic Belt: Advances and perspectives

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