地质学
岩浆作用
俯冲
岩石成因
地球化学
结壳
地幔(地质学)
构造学
捕虏体
岩石学
地壳再循环
地球科学
板块构造
大洋地壳
部分熔融
大陆地壳
地球动力学
榴辉岩
岩石圈
作者
Zhi Zhang,Yingde Jiang,Pavla Štípská,Karel Schulmann,Petra Maierová
摘要
Ultrapotassic rocks are widely considered to originate from a metasomatized mantle source enriched by crustal components; however, mechanisms controlling the crustal inputs remain poorly understood. To address this issue, the petrogenesis of Miocene ultrapotassic volcanics, a vital lithoprobe, from the Lhasa terrane, southern Tibet, is investigated. Their geochemistry shows (1) ultrahigh Th/La ratios, indicating recycling of crustal material at shallow depths (≤80 km), and (2) evolved Sr-Nd isotopic signatures, consistent with contributions from Himalayan sediments and Yarlung Zangbo ophiolite. Phase equilibria modeling of such mixtures at 25 kbar and 900−1100 °C—consistent with xenolith pressure-temperature constraints—produces 10−20 vol% melts resembling the natural ultrapotassic rocks. Integrating geological and geophysical evidence, we propose a tectonic model in which subducted sediments and oceanic crust form a mélange, are relaminated beneath the Tibetan lithosphere, and subsequently melt to generate ultrapotassic magmas. This model provides new insights into crustal recycling in subduction systems in general.
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