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Early Carboniferous Back‐Arc Rifting‐Related Magmatism in Southern Tibet: Implications for the History of the Lhasa Terrane Separation From Gondwana
Tectonics ( IF 3.3 ) Pub Date : 2020-10-16 , DOI: 10.1029/2020tc006237 Xuhui Wang 1 , Xinghai Lang 1, 2 , Juxing Tang 3 , Yulin Deng 1 , Qing He 1 , Fuwei Xie 1 , Liang Li 1 , Qing Yin 1 , Zhijun Li 1 , Zhuang Li 4 , Zongyao Yang 5 , Shuyi Dong 1 , Feng Ding 1 , Zizheng Wang 6 , Yong Huang 6
Tectonics ( IF 3.3 ) Pub Date : 2020-10-16 , DOI: 10.1029/2020tc006237 Xuhui Wang 1 , Xinghai Lang 1, 2 , Juxing Tang 3 , Yulin Deng 1 , Qing He 1 , Fuwei Xie 1 , Liang Li 1 , Qing Yin 1 , Zhijun Li 1 , Zhuang Li 4 , Zongyao Yang 5 , Shuyi Dong 1 , Feng Ding 1 , Zizheng Wang 6 , Yong Huang 6
Affiliation
The Lhasa terrane is widely regarded as an integral unit that separated from Gondwana in the Carboniferous or late Triassic, but this terrane may more reasonably consist of two subterranes that separated from Gondwana at different times. Here, we describe newly identified early Carboniferous (355–344 Ma) basic and intermediate intrusive rocks in the Xiongcun area, southern Tibet. The basic rocks that yield negative whole‐rock εNd(t) values (−5.04 to −2.94) and zircon εHf(t) values (−9.2 to −1.7), combined with the chemical compositions, indicate that the magmas were derived by the partial melting of an enriched lithospheric mantle in a back‐arc extensional setting. The intermediate rocks yield εNd(t) and εHf(t) values of −5.78 to −5.36 and −9.2 to −4.5, respectively, which suggests that they were likely produced via crust‐mantle mixing. By combining our results with those of previous studies on the Lhasa terrane, we consider that a broad back‐arc rift system, including northern and southern branches, developed along the northern margin of Gondwana under the southward subduction of the Paleo‐Tethys oceanic lithosphere during the early Carboniferous. The northern branch evolved into the Sumdo Paleo‐Tethys Ocean, which led to the separation of the North Lhasa terrane from northern Gondwana during the late Carboniferous. The subsequent northward subduction of the Sumdo Paleo‐Tethys oceanic lithosphere beneath the North Lhasa terrane during the early to middle Permian may have triggered the southern branch to further evolve into the Neo‐Tethys Ocean and eventually may have resulted in the South Lhasa terrane separating from Gondwana.
更新日期:2020-10-30
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