Origin of Tibetan post-collisional high-K adakitic granites: Anatexis of intermediate to felsic arc rocks

Yi, Jian-Kang; Zhu, Di‐Cheng; Weinberg, Roberto F.; Wang, Qing; Xie, Jin‐Cheng; Zhang, Liangliang; Zhao, Zhidan

doi:10.1130/g49818.1

Cited by 12 publications

(5 citation statements)

References 35 publications

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“…2g–i ). This is because: (1) the formation of volumetrically insignificant post-collisional hornblende gabbros may indicate a diminished role of fractional crystallization, (2) the early appearance of plagioclase followed by hornblende in hornblende gabbro 35 also suggests damp fractionation, (3) evidence for Miocene migmatization of syn-collisional dioritic gneisses accompanied by post-collisional granitic rocks with xenocrysts from the dioritic gneisses, collectively recording anatexis 36 , and (4) more enriched radiogenic isotope compositions compared to the pre- and syn-collisional samples, along with high Cr and Ni contents, and Mg# (Fig. 2g ) in some Miocene intermediate-to-felsic samples, indicate hybridization between melts derived from the pre-existing Gangdese crust and ultrapotassic magmas from the Gangdese lithospheric mantle metasomatized by subducted Indian continental material 12 .…”

Section: Resultsmentioning

confidence: 99%

Interplay between oceanic subduction and continental collision in building continental crust

et al. 2022

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Generation of continental crust in collision zones reflect the interplay between oceanic subduction and continental collision. The Gangdese continental crust in southern Tibet developed during subduction of the Neo-Tethyan oceanic slab in the Mesozoic prior to reworking during the India-Asia collision in the Cenozoic. Here we show that continental arc magmatism started with fractional crystallization to form cumulates and associated medium-K calc-alkaline suites. This was followed by a period commencing at ~70 Ma dominated by remelting of pre-existing lower crust, producing more potassic compositions. The increased importance of remelting coincides with an acceleration in the convergence rate between India and Asia leading to higher basaltic flow into the Asian lithosphere, followed by convergence deceleration due to slab breakoff, enabling high heat flow and melting of the base of the arc. This two-stage process of accumulation and remelting leads to the chemical maturation of juvenile continental crust in collision zones, strengthening crustal stratification.

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Section: Resultsmentioning

confidence: 99%

Interplay between oceanic subduction and continental collision in building continental crust

et al. 2022

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“…Continued growth of the Gangdese crust from 70 to 10 Ma is recorded by gabbroic to intermediate rocks, which show either positive zircon ε Hf (t) ) originating from depleted mantle and/or melting of juvenile crust or negative zircon ε Hf (t) (Figure 6a,b) from assimilation of enriched continental lithospheric mantle (Yang et al 2015, Ma et al 2017). This period is also characterized by significant crustal reworking marked by the high-K calc-alkaline felsic rocks that dominate this period (Figure 5h-j) and are primarily produced by melting of the preexisting, juvenile middle and lower arc crust (Yi et al 2022. Despite the large uncertainties in the vertical dimension, the amount of crustal growth and reworking at 70-10 Ma can be evaluated using the outcrop areas of different lithologies, as exemplified by the Idaho Batholith in the northern US Cordillera (Gaschnig et al 2017).…”

Section: Crustal Growth Processmentioning

confidence: 99%

“…This is indicated by the presence of ∼85 Ma zircons in ultramafic xenoliths and of 51−45 Ma zircons in dioritic and felsic granulite xenoliths entrained in Miocene ultrapotassic rocks, both of which experienced similar granulite-facies metamorphism at P-T conditions of 15−26 kbar (50−85 km) and 850-1,100°C during 17−13 Ma (Chan et al 2009, Wang et al 2016b. Except for the sporadic intrusions of 20 ± 5 Ma felsic rocks into the middle to upper crust, other exposed middle crustal rocks include the 65−38 Ma dioritic to felsic orthogneisses and paragneisses, which experienced metamorphism and melting at 9−12 kbar (30−40 km) and 710−760°C (Zhang et al 2015, Yi et al 2022. Volumetrically minor Miocene ultrapotassic rocks from the metasomatized mantle lithosphere (Sun et al 2018) (Figure 9g) are an important component that modifies the compositional architecture throughout the crust (Zhu et al 2022) as they are strongly enriched in incompatible trace elements and have evolved isotopic composition.…”

Section: Evolving Crustal Compositional Architecturementioning

confidence: 99%

Continental Crustal Growth Processes Recorded in the Gangdese Batholith, Southern Tibet

Zhu

Wang

Weinberg

et al. 2023

Annual Review of Earth and Planetary Sciences

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The continental crust in the overriding plate of the India-Asia collision zone in southern Tibet is characterized by an overthickened layer of felsic composition with an underlying granulite-eclogite layer. A large data set indicates that this crust experienced magmatism from 245 to 10 Ma, as recorded by the Gangdese Batholith. Magmatism was punctuated by flare-ups at 185−170, 90−75, and 55−45 Ma caused by a combination of external and internal factors. The growth of this crust starts with a period dominated by fractional crystallization and the formation of voluminous (ultra)mafic arc cumulates in the lower crust during subduction, followed by their melting during late-subduction and collision, due to changes in convergence rate. This combined accumulation-melting process resulted in the vertical stratification and density sorting of the Gangdese crust. Comparisons with other similarly thickened collision zones suggests that this is a general process that leads to the stabilization of continental crust. ▪ The Gangdese Batholith records the time-integrated development of the world's thickest crust, reaching greater than 50 km at 55–45 Ma and greater than 70 km after 32 Ma. ▪ The Gangdese Batholith records three magmatic flare-ups in response to distinct drivers; the last one at 55−45 Ma marks the arrival of India. ▪ Magmatism was first dominated by fractional crystallization (accumulation) followed by crustal melting: the accumulation-melting process. ▪ Accumulation-melting in other collision zones provides a general process for vertical stratification and stabilization of continental crust.

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“…They commonly contain higher K 2 O contents and K 2 O/Na 2 O ratios than adakites, and we refer to them as K‐rich adakite‐like rocks (KARs) in this paper. A number of models have been proposed for their formation, including melting of K‐rich basalts in thickened, subducted, or foundered continental crust (e.g., Chen et al., 2013; Chung et al., 2003; Hou et al., 2004; Q. Wang et al., 2005, 2008), hybridization of crust‐derived adakitic magmas with mantle‐derived shoshonitic melts (e.g., Hou et al., 2004; R. Wang et al., 2018; X. Wang et al., 2019; Yang et al., 2015), fractional crystallization of medium‐K basaltic melts represented by mafic microgranular enclaves (Lu et al., 2015), and melting of intermediate to felsic arc rocks in the stability field of garnet (Yi et al., 2022). Most of the models essentially link the KARs with the melting of pre‐existing crustal rocks, and limited attention has been paid to the possibility that they result from fractional crystallization of mantle‐derived, high‐K basaltic melts.…”

Section: Introductionmentioning

confidence: 99%

“…Wang et al, 2018;X. Wang et al, 2019;Yang et al, 2015), fractional crystallization of medium-K basaltic melts represented by mafic microgranular enclaves (Lu et al, 2015), and melting of intermediate to felsic arc rocks in the stability field of garnet (Yi et al, 2022). Most of the models essentially link the KARs with the melting of pre-existing crustal rocks, and limited attention has been paid to the possibility that they result from fractional crystallization of mantle-derived, high-K basaltic melts.…”

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confidence: 99%

K‐Rich Adakite‐Like Rocks in Central Tibet: Fractional Crystallization of a Hydrous, Alkaline Primitive Melt

Weinberg

Tian

et al. 2023

Geophysical Research Letters

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Origin of Tibetan post-collisional high-K adakitic granites: Anatexis of intermediate to felsic arc rocks

Cited by 12 publications

References 35 publications

Interplay between oceanic subduction and continental collision in building continental crust

Interplay between oceanic subduction and continental collision in building continental crust

Continental Crustal Growth Processes Recorded in the Gangdese Batholith, Southern Tibet

K‐Rich Adakite‐Like Rocks in Central Tibet: Fractional Crystallization of a Hydrous, Alkaline Primitive Melt

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