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Guo, Zhengfu, Wilson, Marjorie (2019) Late Oligocene–early Miocene transformation of postcollisional magmatism in Tibet. Geology, 47 (8) 776-780 doi:10.1130/g46147.1

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Reference TypeJournal (article/letter/editorial)
TitleLate Oligocene–early Miocene transformation of postcollisional magmatism in Tibet
JournalGeology
AuthorsGuo, ZhengfuAuthor
Wilson, MarjorieAuthor
Year2019 (August 1)Volume47
Issue8
PublisherGeological Society of America
DOIdoi:10.1130/g46147.1Search in ResearchGate
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Mindat Ref. ID144013Long-form Identifiermindat:1:5:144013:7
GUID0
Full ReferenceGuo, Zhengfu, Wilson, Marjorie (2019) Late Oligocene–early Miocene transformation of postcollisional magmatism in Tibet. Geology, 47 (8) 776-780 doi:10.1130/g46147.1
Plain TextGuo, Zhengfu, Wilson, Marjorie (2019) Late Oligocene–early Miocene transformation of postcollisional magmatism in Tibet. Geology, 47 (8) 776-780 doi:10.1130/g46147.1
In(2019, August) Geology Vol. 47 (8) Geological Society of America
Abstract/NotesAbstract
Uplift of the Tibetan Plateau is thought to be one of the most important orogenic and climate forcing events of the Cenozoic Era, associated with geodynamic changes related to India-Asia collision and subsequent continental lithosphere subduction. However, the fate and scale of the subducted continental lithosphere segments remain highly controversial. Using a comprehensive compilation of the spatiotemporal distribution of postcollisional magmatic rocks across Tibet, together with new geochemical and Sr-Nd-Pb isotopic data and modeling simulations, we propose a holistic, two-stage evolutionary model to explain the link between genesis of the magmas and continental subduction. The magmatism prior to 25 Ma resulted from continuous upwelling of a carbonate-rich upper-mantle plume induced by northward underthrusting of Indian oceanic and continental lithosphere with its cover of Tethyan platform carbonate sediments, whereas magmatism after 25 Ma was related to opposing north-directed and south-directed continental subduction. Our model indicates a transformation in the distribution and nature of the magmatism in Tibet at ca. 25 Ma, which reflects a significant change in the Himalayan-Tibetan orogen and associated mantle dynamic processes in the early Miocene. Understanding this transformation could have important implications for the utility of the Himalayan-Tibetan system as a modern analogue for ancient orogens.

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Guo, Zhengfu, Wilson, Marjorie, Zhang, Lihong, Zhang, Maoliang, Cheng, Zhihui, Liu, Jiaqi (2014) The role of subduction channel mélanges and convergent subduction systems in the petrogenesis of post-collisional K-rich mafic magmatism in NW Tibet. Lithos, 198. 184-201 doi:10.1016/j.lithos.2014.03.020
Guo, Zhengfu, Wilson, Marjorie, Liu, Jiaqi (2007) Post-collisional adakites in south Tibet: Products of partial melting of subduction-modified lower crust. Lithos, 96 (1) 205-224 doi:10.1016/j.lithos.2006.09.011
Guo, Zhengfu, Wilson, Marjorie, Zhang, Maoliang, Cheng, Zhihui, Zhang, Lihong (2013) Post-collisional, K-rich mafic magmatism in south Tibet: constraints on Indian slab-to-wedge transport processes and plateau uplift. Contributions to Mineralogy and Petrology, 165 (6) 1311-1340 doi:10.1007/s00410-013-0860-y
DeCelles, P. G., Kapp, P., Quade, J., Gehrels, G. E. (2011) Oligocene-Miocene Kailas basin, southwestern Tibet: Record of postcollisional upper-plate extension in the Indus-Yarlung suture zone. Geological Society of America Bulletin, 123 (7) 1337-1362 doi:10.1130/b30258.1
Guo, Zhengfu, Wilson, Marjorie, Zhang, Maoliang, Cheng, Zhihui, Zhang, Lihong (2015) Post-collisional Ultrapotassic Mafic Magmatism in South Tibet: Products of Partial Melting of Pyroxenite in the Mantle Wedge Induced by Roll-back and Delamination of the Subducted Indian Continental Lithosphere Slab. Journal of Petrology, 56 (7) 1365-1406 doi:10.1093/petrology/egv040
GUO, ZHENGFU, WILSON, MARJORIE, LIU, JIAQI, MAO, QIAN (2006) Post-collisional, Potassic and Ultrapotassic Magmatism of the Northern Tibetan Plateau: Constraints on Characteristics of the Mantle Source, Geodynamic Setting and Uplift Mechanisms. Journal of Petrology, 47 (6) 1177-1220 doi:10.1093/petrology/egl007
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