Origin of low δ26Mg basalts with EM-I component: Evidence for interaction between enriched lithosphere and carbonated asthenosphere

Many studies have focused on the interactions between recycled materials and depleted mantle to explain the origins of EM and HIMU components (e.g., Cohen and O'Nions, 1982; White and Hofmann, 1982). However, little is known about the interactions between recycled materials and enriched mantle and the associated consequences, e.g., late recycled crustal material overprints mantle previously enriched by earlier recycling events of the crust. Recently, light Mg isotopic composition of the basalts from North China Craton (NCC) and South China Block (SCB) has been attributed to recycled carbonate metasomatism from subducted Pacific slab (Yang et al., 2012; Huang et al., 2015). If this explanation is correct, the Cenozoic basalts from Northeast (NE) China should also contain light Mg isotopic compositions. The basalts from NE China have EMI Sr-Nd-Pb isotopic features that are distinct from the NCC and SCB basalts, indicating the contribution of an enriched mantle source (Choi et al., 2006; Chu et al., 2013). Therefore, Mg isotopic compositions of the Cenozoic basalts from NE China will help to determine the interaction between recycled sedimentary carbonates and an enriched mantle. Consistent with the hypothesis, our results show that the Cenozoic basalts from Wudalianchi and Erkeshan, NE China, have homogeneous and light Mg isotopic compositions (δ26Mg =-0.57 to -0.46‰). Based on the similarity to the basalts from NCC and SCB, their light Mg isotopic feature should also be derived from carbonate metasomatism (i.e. carbonated asthenosphere). In addition to that, a question arise that why the interaction between carbonated asthenosphere and the EM-I SLCM significantly modify the trace element and Sr-Nd-Pb isotopic composition of the mantle-derived melt, but have little effect on the Mg isotopes? The possible mechanism is the interaction between low SiO2 melt and peridotite, which converts pyroxene to olivine, as reported in previous studies (e.g., Kelemen et al., 1992; Edwards and Malpas, 1996; Zhou et al., 1996, 2014). During the interaction, the trace elements of the EM-I SCLM largely entered the melt, and all Mg was transferred from Opx and Cpx into the newly formed olivine. Consequently, the Wudalianchi and Erkeshan basalts preserve low δ26Mg and obtain EM-I Sr-Nd-Pb isotopic compositions (Fig. 1).