Binary metal oxide anchored into dense N-doped CNTs arrays: Concerted pseudocapacitance and diffusion behavior for long-cyclic Li-ion half/full batteries

A hierarchical nanosheet of binary metal oxide (ZnO/Co3O4) anchored into dense N-doped CNTs arrays (ZCO/NCNTs) was derived by two-step calcination. The design of ZCO/NCNTs containing binary metal oxides can better coordinate the pseudo-capacitance behavior of Co3O4 and the ion diffusion behavior of ZnO to realize a long-term stability for lithium storage at various current densities. Furthermore, the presence of slight Zn sources increases the catalytic efficiency of Co towards the growth of graphitized carbon during calcination process, resulting in the formation of dense carbon nanotubes for enhanced carrier transport. The strong interaction between the metal oxides and carbon nanotubes can accommodate the bulk expansion of electrode, obtaining high reversible capacity (∼880 mAh g−1) and long cycle stability (>500 cycles). Thus, the full cell of LiFePO4||CZO/NCNTs at 0.3 A g−1 exhibits excellent cycle stability with good retention rate after 200 cycles. This study provides a new basis for the improvement of lithium storage performance of metal oxide anode. [Display omitted] •The ZCO/NCNTs anode containing binary metal oxides and dense carbon nanotubes is designed.•The concerted pseudocapacitance and diffusion behavior of typical binary metal oxides is firstly discussed.•Strong interaction between the metal oxides and carbon nanotubes accommodate the bulk expansion of electrode.•Li-ion half/full cells show superior rate performance and durable cyclic stability. Electrode material is a crucial role to improve the performance of alkali metal ion batteries. Herein, a hierarchical nanosheet of binary metal oxide (ZnO/Co3O4) anchored into dense N-doped CNTs arrays (ZCO/NCNTs) was derived by two-step calcination. The design of ZCO/NCNTs containing binary metal oxides can better coordinate the pseudo-capacitance behavior of Co3O4 and the ion diffusion behavior of ZnO to realize a long-term stability for lithium storage at various current densities. Furthermore, the presence of slight Zn sources increases the catalytic efficiency of Co towards the growth of graphitized carbon during calcination process, resulting in the formation of dense carbon nanotubes for enhanced carrier transport. The strong interaction between the metal oxides and carbon nanotubes can accommodate the bulk expansion of electrode, obtaining high reversible capacity (∼880 mAh g−1) and long cycle stability (>500 cycles). Thus, the full cell of LiFePO4||CZO/NCNTs at 0.3 A g−1 exhibits excellent