To develop more efficient catalysts that can be operated at low temperature region for oxidative of methane (OCM), a series of Ln2Ce2O7 compounds with different A sites (Ln = La, Pr, Sm and Y) have been prepared. It is revealed by XRD and Raman techniques that a defective cubic fluorite phase has been formed in all the catalysts. As a consequence, all the Ln2Ce2O7 catalysts possess much stronger surface basicity and more abundant electrophilic oxygen species in comparison with individual CeO2, which is beneficial to OCM reaction. It is believed that the concerted interaction between surface intermediate basic sites and selective electrophilic oxygen species is the predominant reason controlling the reaction performance of the catalysts. Furthermore, Ln2Ce2O7 catalysts own more abundant mesopores and higher surface areas than pure CeO2, which could also be favorable for the contacting of the reactants with the active sites. Due to the optimal synergistic interaction of these factors, La2Ce2O7 exhibits the best performance among all the catalysts, on which the highest C2 yield of 16.6% is achieved at 750 °C. In comparison with Mn/Na2WO4/SiO2, the most promising catalyst at present, La2Ce2O7 display much improved reaction performance at low temperature region (<750 °C).