Isotopes Features of the Intrusive Rocks in the Xigaze Ophiolite, Southern Tibet: Constraints on its Formation Setting

High-silica (<70 wt% SiO2) magmas are usually believed to form via shallow crustal–level fractional crystallization of intermediate magmas. However, the broad applicability of this model is controversial, because the required crystal-melt separation processes have rarely been documented globally up to now. The ca. 50 Ma Nyemo composite pluton of the Gangdese batholith belt in southern Tibet, which comprises intrusive rocks with intermediate- to high-silica compositions (65–78 wt%), offers a unique opportunity for substantiating the coexistence of extracted melts and complementary silicic cumulates in one of Earth’s most complete transcrustal silicic magmatic systems. The Nyemo pluton intrusive rocks exhibit similar zircon Hf isotopic compositional ranges (mean εHf(t) = +5.7 to +8.3), suggesting a common, non-radiogenic magma source with crustal assimilation in the deep crust. Yet, these rocks have distinct geochemical characteristics. High-silica miarolitic and rapakivi granites are strongly depleted in Ba, Sr, and Eu, and their zircon trace elements show extremely low Eu/Eu* and Dy/Yb. In contrast, monzogranite is relatively enriched in Ba and Sr with minor Eu anomalies, and the zircon trace elements are characterized by relatively high Eu/Eu* and Dy/Yb. Therefore, we propose that the high-silica granites represent highly fractionated melt extracted from a mush reservoir at unusually low storage pressure (~99–119 MPa), and that the monzogranite constitutes the complementary residual silicic cumulates.

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Reply to comment by Vind et al. on “the role of clinopyroxene in amphibole fractionation of arc magmas: Evidence from mafic intrusive rocks within the Gangdese arc, southern Tibet”

Lithos ◽

10.1016/j.lithos.2020.105721 ◽

2020 ◽

pp. 105721

Author(s):

Jun Wang ◽

Qiang Wang ◽

Wei Dan

Keyword(s):

Southern Tibet ◽

Arc Magmas ◽

Intrusive Rocks ◽

Amphibole Fractionation

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Geochemical characteristics and petrogenesis of Late Cretaceous hypersthene-bearing intrusive rocks in the Gangdese batholith, southern Tibet

Acta Petrologica Sinica ◽

10.18654/1000-0569/2020.09.05 ◽

2020 ◽

Vol 36 (9) ◽

pp. 2667-2700

Author(s):

GAO JiaHao ◽

◽

ZENG LingSen ◽

GAO LiE ◽

ZHAO LingHao ◽

...

Keyword(s):

Late Cretaceous ◽

Geochemical Characteristics ◽

Southern Tibet ◽

Intrusive Rocks

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Gangdese magmatism in southern Tibet and India–Asia convergence since 120 Ma

Geological Society London Special Publications ◽

10.1144/sp483.14 ◽

2018 ◽

Vol 483 (1) ◽

pp. 583-604 ◽

Cited By ~ 25

Author(s):

Di-Cheng Zhu ◽

Qing Wang ◽

Sun-Lin Chung ◽

Peter A. Cawood ◽

Zhi-Dan Zhao

Keyword(s):

Oceanic Lithosphere ◽

Southern Tibet ◽

Ridge Subduction ◽

Slab Rollback ◽

Rate Acceleration ◽

Slab Breakoff ◽

Magmatic Temperature ◽

Intrusive Rocks ◽

Rate Deceleration ◽

Compositional Diversity

AbstractA compilation of 290 zircon U–Pb ages of intrusive rocks indicates that the Gangdese Batholith in southern Tibet was emplaced from c. 210 Ma to c. 10 Ma. Two intense magmatic pulses within the batholith occur at: (1) 90 ± 5 Ma, which is restricted to 89–94° E in the eastern segment of the southern Lhasa subterrane; and (2) 50 ± 3 Ma, which is widespread across the entire southern Lhasa subterrane. The latter pulse was followed by a phase of widespread but volumetrically small, dominantly felsic adakitic intrusive rocks at 16 ± 2 Ma. The Linzizong volcanism in the Linzhou Basin was active from 60.2 to 52.3 Ma, rather than 69–44 Ma as previously estimated. During 120–75 Ma, Gangdese Batholith magmatism migrated from south to north, arguing against rollback of the downgoing, north-dipping Neo-Tethyan oceanic lithosphere for the generation of the 90 ± 5 Ma magmatic pulse. Petrological, geochemical and metamorphic data indicate that this pulse was likely to have been generated through subduction of the Neo-Tethyan oceanic ridge lithosphere. Subsequent Gangdese Batholith magmatism propagated both south and north during 70–45 Ma, and finally concentrated at the southern margin of the Lhasa Terrane at 45–30 Ma. The enhanced mafic magmatism since c. 70 Ma, magmatic flare-up with compositional diversity at c. 51 Ma and increased magmatic temperature at 52–50 Ma are interpreted as the consequences of slab rollback from c. 70 Ma and slab breakoff of the Neo-Tethyan oceanic lithosphere that began at c. 53 Ma. The India–Asia convergence was driven by Neo-Tethyan subduction with a normal rate of convergence at 120–95 Ma, ridge subduction at 95–85 Ma, then subduction of a young and buoyant oceanic lithosphere after ridge subduction with rate deceleration at 84–67 Ma, Deccan plume activity and slab rollback with rate acceleration at 67–51 Ma, slab breakoff for sudden drop of the convergence rate at c. 51 Ma, and finally the descent of the high-density Indian continental lithosphere beneath Asia since c. 50 Ma.

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