Boron and Molybdenum Isotope Evidence for Source‐Controlled Compositional Diversity of Cenozoic Granites in the Eastern Tethyan Himalaya

Abstract: The origins of Cenozoic granites in the Himalaya are key to understanding the evolution of the Himalayan orogen. However, it is unclear whether these granites represent primary melts, and the nature of their magma source is controversial. Here, we present a systematic element and Sr–Nd–B–Mo isotope study of Cenozoic granites from the Yardoi area in the eastern Tethyan Himalaya, China. These granites can be divided into two groups: mid‐Eocene porphyritic two‐mica granites with low SiO2 contents (65.9−69.6 wt.%)… Show more

“…The very low B/Nb ratios of these post‐collisional ultrapotassic rocks indicate a fluid‐starved source and their low δ 11 B values cannot be derived from oceanic sediments or a stalled dehydrated oceanic slab. Combined with the light B isotope compositions of the schists and gneisses of the Tethyan Himalaya (Fan et al., 2023), Hao, Wang, Kerr, et al. (2022) proposed that the very light B isotope compositions of these post‐collisional ultrapotassic rocks in southern Tibet are most likely derived from the subducted Indian continental crust.…”

“…The early Cretaceous arc‐like basalts from the Liaodong Peninsula (Fang et al., 2022) related to continental subduction show low δ 98/95 Mo values (−0.98 to −0.16‰), low Mo/Ce ratios (Figure 4a) and enriched Nd isotopes (Figure 4d), which are similar to those of the Sailipu ultrapotassic rocks. In the case of southern Tibet, the schists and gneisses of the Tethyan Himalaya, as representative examples of Indian continental crust, have extremely low δ 98/95 Mo values (−1.03 to −0.64‰) and Mo/Ce ratios (0.0001–0.009, Fan et al., 2023) (Figure 4a). Moreover, the Sailipu post‐collisional ultrapotassic rocks have δ 98/95 Mo values and Mo/Ce ratios that are intermediate between those of MORBs and the Indian continental crust (Figure 4a).…”

Light Mo Isotopes of Post‐Collisional Ultrapotassic Rocks in Southern Tibet Derived From Subducted Indian Continental Crust

“…The very low B/Nb ratios of these post‐collisional ultrapotassic rocks indicate a fluid‐starved source and their low δ 11 B values cannot be derived from oceanic sediments or a stalled dehydrated oceanic slab. Combined with the light B isotope compositions of the schists and gneisses of the Tethyan Himalaya (Fan et al., 2023), Hao, Wang, Kerr, et al. (2022) proposed that the very light B isotope compositions of these post‐collisional ultrapotassic rocks in southern Tibet are most likely derived from the subducted Indian continental crust.…”

“…The early Cretaceous arc‐like basalts from the Liaodong Peninsula (Fang et al., 2022) related to continental subduction show low δ 98/95 Mo values (−0.98 to −0.16‰), low Mo/Ce ratios (Figure 4a) and enriched Nd isotopes (Figure 4d), which are similar to those of the Sailipu ultrapotassic rocks. In the case of southern Tibet, the schists and gneisses of the Tethyan Himalaya, as representative examples of Indian continental crust, have extremely low δ 98/95 Mo values (−1.03 to −0.64‰) and Mo/Ce ratios (0.0001–0.009, Fan et al., 2023) (Figure 4a). Moreover, the Sailipu post‐collisional ultrapotassic rocks have δ 98/95 Mo values and Mo/Ce ratios that are intermediate between those of MORBs and the Indian continental crust (Figure 4a).…”

Light Mo Isotopes of Post‐Collisional Ultrapotassic Rocks in Southern Tibet Derived From Subducted Indian Continental Crust

Central Tibetan adakitic rocks archive the critical impact of water on the Nb/Ta variation in deep crustal melts

Boron isotopes in tourmaline from drill core of the Jiajika granitic pegmatite type lithium deposit: Insights for granitic magma evolution and lithium enrichment