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Redox state of southern Tibetan upper mantle and ultrapotassic magmas

Weikai Li, Zhiming Yang, Massimo Chiaradia, Yong Lai, Chao Yu, Jiayu Zhang

2020Geology55 citationsDOIOpen Access PDF

Abstract

Abstract The redox state of Earth’s upper mantle in several tectonic settings, such as cratonic mantle, oceanic mantle, and mantle wedges beneath magmatic arcs, has been well documented. In contrast, oxygen fugacity () data of upper mantle under orogens worldwide are rare, and the mechanism responsible for the mantle condition under orogens is not well constrained. In this study, we investigated the of mantle xenoliths derived from the southern Tibetan lithospheric mantle beneath the Himalayan orogen, and that of postcollisional ultrapotassic volcanic rocks hosting the xenoliths. The of mantle xenoliths ranges from ΔFMQ = +0.5 to +1.2 (where ΔFMQ is the deviation of log from the fayalite-magnetite-quartz buffer), indicating that the southern Tibetan lithospheric mantle is more oxidized than cratonic and oceanic mantle, and it falls within the typical range of mantle wedge values. Mineralogical evidence suggests that water-rich fluids and sediment melts liberated from both the subducting Neo-Tethyan oceanic slab and perhaps the Indian continental plate could have oxidized the southern Tibetan lithospheric mantle. The conditions of ultrapotassic magmas show a shift toward more oxidized conditions during ascent (from ΔFMQ = +0.8 to +3.0). Crustal evolution processes (e.g., fractionation) could influence magmatic , and thus the redox state of mantle-derived magma may not simply represent its mantle source.

Topics & Concepts

GeologyMantle (geology)Mantle wedgeMineral redox bufferTransition zoneHotspot (geology)GeochemistryXenolithLithosphereMantle plumeMantle convectionPetrologyGeophysicsTectonicsPaleontologyGeological and Geochemical AnalysisHigh-pressure geophysics and materialsearthquake and tectonic studies
Redox state of southern Tibetan upper mantle and ultrapotassic magmas | Litcius