Early cretaceous granitoids in the Southern Pamir: Implications for the Meso-Tethys evolution of the Pamir Plateau

Abstract Although it is generally accepted that the Pamir was formed by long-term terrane drifting and accretion to the south margin of the Asia, the tectonic evolution during the Mesozoic remains unclear. The voluminous Cretaceous intrusions in the Southern Pamir-Karakorum provide key information for understanding the Mesozoic evolution in this region. In this contribution, we report detailed petrography, ages, mineral geochemistry, whole-rock elemental and Sr Nd geochemistry and in situ zircon Lu Hf isotopic compositions of the Early Cretaceous granitoids from the Chinese Wakhan Corridor, Southern Pamir. These granitoids are composed primarily of granodiorite and minor monzogranite and host dioritic enclaves. The granitoids were emplaced at 107–102 Ma, based on their zircon U Pb ages. They have 63–73 wt% SiO2, Mg# between 39 and 53 and ACNK mostly lower than 1.1, and are I-type granites. The granitoids display arc-like geochemical signatures characterized by LREE-enriched patterns, variable negative Eu anomalies (LaN/YbN = 11.38–23.27; Eu/Eu* = 0.36–0.74), and a significant Nb Ta trough (Nb/La = 0.24–0.41). Isotopically, the granitoids have negative whole-rock eNd(t) (−8.73–-7.35) and zircon eHf(t) (−17.7–-5.3) values. The coeval dioritic enclaves (ca. 104 Ma) contain 57–63 wt% SiO2, and have high Mg# (46–57), low Cr (6.86–79.50 ppm), and Ni (2.88–10.00 ppm). These enclaves exhibit arc-like trace element patterns (Nb/La = 0.34–0.43) with variable negative Eu anomaly (Eu/Eu* = 0.52–0.87), uniform whole-rock eNd(t) (−4.74–-4.73), and a large range of zircon eHf(t) values (−13.3–-3.7). In line with their rock association and geochemistry, we suggest that the dioritic enclaves were derived from melting of a phlogopite-bearing mantle source modified by subduction-related process, followed by fractional crystallization and later assimilation by granitic hosts. These Early Cretaceous granitoids were most likely generated by partial melting of the Precambrian lower crust with variable involvement of mafic magma parental to the dioritic enclaves. Our new data, combined with the previous studies, reveal that the widespread Early Cretaceous magmatism in the Southern Pamir-Karakorum were most likely generated by flat-slab subduction of the Meso-Tethys Ocean during the Cretaceous.