Petrogenesis of volcanic rocks of the Devonian – Carboniferous Dahalajunshan Formation, Western Tianshan: Implications for crustal growth in an accretionary orogen

Magmatism associated with plate subduction and collision plays an important role in crustal growth during the evolution of the Earth, but the detailed mechanisms regarding how magmatism contributes to the vertical growth of the crust remain unclear, in part due to controversies on the petrogenesis of intermediate-felsic rocks. In the Central Asian Orogenic Belt (CAOB), although it has been recognized that both pre-existing crustal component and juvenile mantle-derived melt played a role in the crustal evolution of the orogens, the mechanics of how they contributed to vertical crustal growth remain uncertain. This study presents new geochronological, major and trace element geochemical, and Nd–Hf isotopic data for the Late Paleozoic intermediate-felsic volcanic rocks of the northern Yili terrane, Western Tianshan Orogen, with the aims to constrain the petrogenesis of the andesitic magma and to offer new insights into the deep interaction processes between crustal- and mantle-derived magmas. According to zircon U–Pb dating, trace element and isotopic compositional data, these volcanic rocks can be divided into two groups. Group 1 rocks (365–375 Ma) have relatively low whole-rock εNd(t) values (−4.2 – −1.6) and display high contents of Th (11.8–20.4 ppm), U (2.7–5.1 ppm), Nb (14.1–36.7 ppm) and Ta (1.1–3.1 ppm) that suggest they were derived from the partial melting of pre-existing crust. Group 2 rocks (346–349 Ma) show REE and trace elemental patterns typical of subduction-related calc-alkaline volcanic rocks with relatively high whole-rock εNd(t) values (−1.89 – +2.4), and with variable zircon Hf isotopic values (εHf(t) = +1.9 – +13.5) that can be attributed a juvenile crust with variable input of mantle material. Hf–Nd isotopic decoupling of the group 2 rocks suggests a replenishment by more mafic magmas. Samples from the entire Yili terrane show an increasing trend in εNd(t) values with younger ages that suggest an increasing involvement of melted juvenile crustal rocks. Overall, these results suggest a crustal evolutionary scenario in which: 1) pre-existing crustal components were melted and ascended to the upper crust (group 1) during the southward subduction of the Junggar-North Tianshan ocean in the early stage; and, 2) a later stage in which newly input mantle material solidified to form new arc crust that was also melted by basaltic underplating and that was probably associated with the rollback of the Junggar oceanic slab. This two-stage crustal growth model seems to be an efficient process for vertical crustal growth during the formation of an accretionary orogen.