General synthesis of graphene-supported bicomponent metal monoxides as alternative high performance Li-ion anodes to binary spinel oxides

Engineering two transition metals into an integrated spinel oxide anode provides great opportunity towards high-performance lithium-ion batteries (LIBs). Spinels with high-valence transition metal oxides (TMOs) however tend to exhibit low initial coulombic efficiency (ICE) due to the irreversible Li2O generated during the first discharge process. Herein, we report a simple and general strategy to synthesize elaborate graphene framework (GF) supported low-valence bicomponent transition metal monoxide anodes (e.g., ZnO-MnO microcubes, ZnO-CoO polyhedra, NiO-CoO nanowires, and (FeO)(0.333)(MnO)(0.667) microspheres, etc.), which can efficiently address the low ICE issue. As a proof of concept demonstration, we show that the ZnO-MnO/GF is indeed more advantageous as an LIB anode over the spinel ZnMn2O4/GF counterpart as well as many other ZnMn2O4-based anodes. Benefiting from the enhanced reversibility of Li+ uptake/extraction and graphene hybridization, the ZnO-MnO/GF electrode exhibits significantly improved ICEs at various current densities, superior rate capability (286 mA h g(-1) even at a high current density of 6 A g(-1); similar to 2.9 min charging/discharging), and extended cycling life (1123 mA h g(-1) after 300 cycles) with respect to ZnMn2O4/GF. Such improvements have also been observed for the ZnO-CoO/GF electrode and other analogues. This versatile electrode design could advance our understanding and control of complex TMO-based anodes to gain high ICE and capacity.