Your search keyword '"Shen Di"' showing total 5 results

1. Tectonic evolution of the north Lhasa subterrane: insights from early Cretaceous marine strata in the Asuo area, central Tibet.

Author

Shen, Di, Wang, Ming, Yu, Chang-sheng, Zhang, Sheng-shuo, and Tenzin, Trevon

Subjects

*ADAKITE, *SUBDUCTION zones, *PALEOGEOGRAPHY, *VOLCANIC ash, tuff, etc., *REGOLITH, *GEOCHEMISTRY, *ANDESITE, *WATER depth

Abstract

The mid-Cretaceous Langshan Formation, which crops out on the north Lhasa subterrane, central Tibet, is composed of a thick carbonate sequence with local volcanic rock and sandstone interlayers. In this study, we present data from the Asuo area, including fossil assemblages within carbonates, detrital zircon U–Pb ages of sandstone interlayers, zircon U–Pb ages and whole-rock geochemistry of andesite interlayers within the Langshan Formation to provide new constraints on the tectonic evolution of north Lhasa subterrane. The fossil assemblage indicates that the Langshan Formation was deposited on a carbonate platform at water depths of approximately 0–50 m during the late Albian to early Cenomanian period. The volcanic rock interlayers (111–109 Ma) primarily consist of high-K calc-alkaline andesites/dacites (SiO2: 56.48–67.03 wt. %; Mg#: 42.5–58.9). These andesites exhibit limited evidence of significant modification by crustal contamination. The high Mg# values and arc-like trace element signatures suggest that the andesites may have resulted from partial melting of the mantle wedge induced by fluids derived from a subducted slab. Furthermore, the lithic fragments within the sandstone interlayers predominantly exhibit characteristics of "recycled orogen" and "arc orogen," indicating that the sandstone was derived from recycled ancient strata and a few magmatic arc materials. Considering the regional paleogeographic context, the carbonate accumulation of the Langshan Formation appears to have occurred nearly simultaneously with a period of high-flux magmatism, long-term slow tectonic subsidence, and the closure of the Meso-Tethys Ocean. The arc–arc "soft" collision provides a plausible mechanism to explain the widespread and rapid accumulation of thick carbonates in collision settings. It also accounts for the presence of magmatic rocks with enhanced mantle contributions on both sides of the north Lhasa subterrane. [ABSTRACT FROM AUTHOR]

Published

2023

2. Discovery of Late Cretaceous basalts in the Asuo area, Central Tibet: Implications for orogenic root removal beneath the Lhasa-Qiangtang orogenic belt.

Author

Shen, Di, Wang, Ming, Yu, Chang-sheng, Danzeng, Quewang, Zhang, Sheng-shuo, Zhou, Jin-lu, and Hao, Bin-xuan

Subjects

*MAFIC rocks, *URANIUM-lead dating, *INCLUSIONS in igneous rocks, *MAGMAS, *ZIRCON, *OROGENIC belts

Abstract

• Discovery of arc-like mafic dikes (ca. 95–75 Ma) in Asuo area, central Tibetan plateau. • The Asuo mafic rocks may result from the crustal assimilation of the mafic magma originating from the metasomatized mantle. • Lithospheric dripping was a potential mechanism to explain post-collisional magmatism in the Lhasa-Qiangtang Orogenic Belt. Post-collisional mafic rocks provide valuable insights into the mantle properties and evolution of orogenic belts. However, their origins remain unknown. In this study, comprehensive age, elemental, and zircon Lu–Hf isotopic data are presented for mafic dikes from the Asuo area of the Central Tibetan Plateau. The Asuo mafic dikes exhibit typical arc-related characteristics such as enrichment in large-ion lithophile elements and depletion in high-field-strength elements. This sodium-rich calc-alkaline mafic rocks has low K 2 O contents (0.98–1.26 wt%) and high Na 2 O/K 2 O ratios (2.55–2.97). The presence of xenolith zircons and varying zircon Hf isotopic composition [ε Hf (t): 1.33–8.32] indicate that the mafic magma assimilated juvenile crust. Zircon U-Pb dating results suggest that the Asuo mafic rocks were emplaced contemporaneously with the adakite-like rocks during ∼ 95–75 Ma. However, no genetic link between Asuo mafic rocks and the adakite-like rocks in the Lhasa–Qiangtang Orogenic belt was observed. The primary contribution of mantle-derived mafic magmas to the formation of coeval intermediate–felsic magmas is the provision of additional heat. The mass exchange between them may be limited. We suggest a geodynamic scenario in which the orogenic root may have been removed during the post-collisional period via repeated and localized lithospheric dripping. In this model, the formation of mafic and adakite-like intrusions occurred in two stages, that is, (1) partial melting of metasomatized lithospheric mantle generated mafic melts, and (2) underplating of these mafic melts beneath the thickened juvenile lower crust, which resulted in partial melting of the juvenile mafic lower crust and generation of adakite-like melts. Our results provide new insights into the magmatism in the terminal stage of an orogenic system. [ABSTRACT FROM AUTHOR]

Published

2024

3. North Lhasa terrane in the Precambrian originated from Western Australia.

Author

Yu, Changsheng, Wang, Ming, Shen, Di, Lin, Mengxian, Zhang, Shengshuo, Yang, Rui, and Quewang, Danzeng

Subjects

*SUPERCONTINENT cycles, *IGNEOUS rocks, *PRECAMBRIAN, *PHANEROZOIC Eon, *ZIRCON, *CONTINENTS

Abstract

• A new Neoproterozoic stratum is determined in North Lhasa terrane. • The stratum is an intercontinental rift sedimentation (∼875 Ma). • Detrital zircons of the stratum exhibit both Australian and Indian characteristics. • North Lhasa originated from Western Australia. • North Lhasa experienced the Precambrian evolution of "rift–drift–emplacement". Constraining the origin and Paleogeographic positions of ancient continental fragments plays a crucial role in reconstructing and validating supercontinent cycles. The Lhasa terrane in southern Tibet is the key to revealing the early formation and evolution of the Himalayan–Tibetan orogen. Although previous origin models of the Lhasa terrane are supported by Phanerozoic evidence, Precambrian geological records have not been comprehensively considered. The U–Pb age and Hf isotope data on detrital zircons from newly discovered Precambrian basement in the North Lhasa terrane define two distinctive age populations of ca. 1170 Ma with ε Hf (t) values identical to the coeval detrital zircons from Western Australia, and ca. 950 Ma with a similar ε Hf (t) range to the contemporaneous detrital zircons from South Qiangtang and Tethyan Himalaya terranes. The ca. 1170 Ma detrital zircons were most likely derived from Western Australia, whereas the ca. 950 Ma detrital zircons might have been sourced from the norther Indian margin. Compiled detrital zircon data shows that in the early Neoproterozoic, the affinity between northern Lhasa and Western Australia decreased, while the predilection between northern Lhasa and northern India increased. Combined with ca. 930–870 Ma rift, ca. 870–700 Ma arc igneous rocks and ∼650 Ma high-pressure granulites, we propose that the North Lhasa terrane was a ribbon continent that rifted from Western Australia in the early Neoproterozoic (ca. 930–870 Ma), drifted westward along the northern edge of Rodinia in the middle Neoproterozoic (ca. 870–700 Ma), and was emplaced in the Northern East African Orogen during the late Neoproterozoic (∼650 Ma). [ABSTRACT FROM AUTHOR]

Published

2024

4. Response of the North Lhasa terrane to the initial break-up of Rodinia: Evidence from the newly identified early Neoproterozoic gabbros in the Asa area, southern Tibet.

Author

Yu, Changsheng, Wang, Ming, Shen, Di, Zeng, Xiaowen, and Li, Hang

Subjects

*GABBRO, *THOLEIITE, *PRECAMBRIAN, *BASEMENTS, *RIFTS (Geology), RODINIA (Supercontinent)

Abstract

• A New Precambrian basement has been identified in Asa region, southern Tibet. • The emplacement age of gabbro intrusions in this basement is ca. 875 Ma. • These gabbro intrusions were formed in an intercontinental rift environment. • The North Lhasa terrane may originate from Australia. Due to the less exposure of Precambrian basement, the origin of ancient continental blocks in the Tibetan plateau and their paleogeographic locations in the Rodinia supercontinent remain enigmatic. Here we first report the newly identified Precambrian basement from the Asa region of the North Lhasa terrane (NL), southern Tibet. The zircon U–Pb age and whole-rock geochemical data on gabbro intrusions (known as Tugu gabbros) in this basement reveal an important tectonic evolution process of continental-oceanic transition experienced by the North Lhasa terrane in the early Neoproterozoic (ca. 900–875 Ma), which may be the prelude to the disintegration of Rodinia in China. Tugu gabbros (ca. 876–874 Ma) belong to the series of sub-alkaline tholeiitic basalt and have N-MORB geochemical affinities. In combination, the high (87Sr/86Sr) i ratios (0.709–0.711), positive ε Nd (t) values (2.8–3.9) and the relatively young Nd isotopic pattern age (t DM C = 1.2–1.3 Ga) indicate that it came from a depleted mantle source and were formed in an intercontinental rift environment on the northern margin of Rodinia. According to previous studies and data provided herein, the era and nature of Precambrian magmatic-metamorphic records in North and South Lhasa terranes cannot be compared, suggesting these may have been two separate terranes in the Precambrian. We propose that the South Lhasa terrane (SL) originated from India, while the North Lhasa terrane may originate from Australia. After splitting from Australia at ca. 930–875 Ma, the North Lhasa terrane continued to drift westward owing to the break-up of Rodinia. During the process of drifting, the North Lhasa terrane received sedimentary input from India and developed Andean-type arc magmatism with the influence of oceanic subduction on the northwest margin of supercontinent. [ABSTRACT FROM AUTHOR]

Published

2023

5. Diachronous closure of the Mesotethys along the Shiquanhe-Namco mélange belt: Evidence from age and nature of the Aptian turbidites in Central Tibet.

Author

Zeng, Xiao-Wen, Wang, Ming, Li, Hang, Zeng, Xian-Jin, and Shen, Di

Subjects

*PROVENANCE (Geology), *TURBIDITES, *ZIRCON analysis, *ACCRETIONARY wedges (Geology), *SEDIMENT transport, *ZIRCON, *SANDSTONE

Abstract

As a part of the Bangong-Nujiang suture, the Shiquanhe-Namco ophiolite mélange belt (SNM), together with the Bangong-Nujiang ophiolite mélange belt (BNM), records the evolutionary history of the Mesotethys. In terms of the closure of the Mesotethys, previous sedimentological research has focused on the BNM, while the SNM remains insufficient. On the basis of detrital zircon dating and sedimentologic data, in this study, we determined the existence of Aptian deep-marine turbidites in the Zhongcang and Lhakorco areas of the SNM. Sandstone petrographic and detrital zircon analysis combine to show that the Zhongcang turbidites provide records of the recycled from the accretionary complex and Triassic-Jurassic strata in the southern Qiangtang margin, with the minor addition of Qiangtang magmatic arc rocks, while sediments in the Lhakorco turbidites were derived mainly from recycled orogen source and Late Jurassic-Early Cretaceous magmatic arc in the Lhasa Terrane. Further analysis suggests that the Aptian turbidites were deposited in a deep-marine oceanic basin of Mesotethys and this oceanic basin prevented Qiangtang-derived sediments transported onto the Lhasa terrane. The Mesotethys experienced diachronic closure from east to west during the Early Cretaceous, and the final closure was most likely completed along the SNM after Aptian. • Discovery of the Aptian deep-marine fan turbidities in SNM • Featuring the Aptian Qiangtang and Lhasa source separation along SNM • Implications for diachronous closure of the Mesotethys [ABSTRACT FROM AUTHOR]

Published

2022