Integrated Carbon Nanotube/MoO3 Core/Shell Arrays as Freestanding Air Cathodes for Flexible Li-CO2 Batteries

Li-CO2 batteries are a hopeful candidate for electrochemical energy storage applications by converting the greenhouse gas CO2 to chemicals. However, the energy harvest ability and cycling stability of powder catalysts have greatly restricted the practical application of this technique. Herein, chemical vapor deposition (CVD) and atomic layer deposition (ALD) methods are used to produce MoO3 -coated carbon nanotube (MoO3@CNT) arrays as cathode catalyst materials for Li-CO2 batteries. The interwoven structure of CNTs provides substantial electron transport pathways and the high uniformity of deposition enhances the catalytic activity/stability of the whole electrode, effectively promoting the diffusion of CO2 during the discharge process and accelerating the decomposition of Li2CO3 under low charge overpotential. At a current density of 0.05 mAcm(-2) and a fixed capacity of 1 mAh cm(-2), the as-prepared electrode presents a competitively low charging overpotential (1 V), an impressive lifetime (300 cycles) and ultrahigh total discharge capacity (30.25 mAh cm(-2)). Using the pouch Li-CO2 battery packed with the prepared electrode as the power supply, commercial light emitting diode equipment can be stably lit up under different bending angles. The research results promote the application of Li-CO2 batteries in portable systems.

Automated summary

By using MoO3@CNT arrays as cathode catalyst materials, the Li-CO2 batteries show enhanced charging efficiency and cycling stability, promoting CO2 diffusion and accelerating Li2CO3 decomposition, leading to a competitively low charging overpotential, impressive lifetime, and ultrahigh total discharge capacity for the electrode.