Photoassisted Li–CO<sub>2</sub> Batteries with Ultrahigh Energy Efficiency and Cycle Stability by a Redox Mediator
Kang Hu, Tingsong Hu, Tengyu Yao, Xueliang Cui, Qiuju Li, Laifa Shen
Abstract
Li–CO 2 batteries are considered promising energy storage systems for implementation in space applications. However, unsatisfactory overpotentials and poor cycling stability caused by the sluggish reaction kinetics of CO 2 reduction and evolution have greatly limited the practical application of Li–CO 2 batteries. Herein, we introduce a redox mediator LiI to stabilize the Bi 5 O 7 I photocathode by the successive separation of electrons and holes to accelerate the sluggish kinetics. Under illumination, LiI allows photogenerated holes to preferentially react with I – in the solid–liquid interface, thereby inhibiting the release of I – from Bi 5 O 7 I and effectively improving the lifespan of the photocathode. Thus, a high discharging platform of 3.05 V and an ultralow charging platform of 3.09 V are achieved to exhibit an energy efficiency of 98.8%. Moreover, a significantly enhanced reversibility is attained, attributed to the decomposition of Li 2 CO 3, which further extends the cycle life to 250 h. This double-phase catalytic strategy demonstrates effectiveness in the development of high-performance Li–CO 2 batteries and other energy storage devices.