Hierarchical Porous Bi<sub>2</sub>Te<sub>3</sub>@C for Wide-Temperature-Range Aqueous Zn-Based Batteries with Air-Recharging Capability
Yixin Hou, Pengfei Ma, Fei Long, Mingyang Liu, Yifan Zheng, Li Sun, Junjie Shi, Ke Niu, Jun Su, Yanan Ma, Yihua Gao
Abstract
Air-rechargeable batteries integrating energy harvesting, conversion, and storage provide the most portable and popular approach to self-charging power systems. However, air-rechargeable batteries are currently mostly aqueous Zn-based battery systems in which it has remained a significant challenge to solve the low discharge capacities and poor cycling stability of chemical self-charging due to continuous insertion/extraction of large-size hydrated Zn 2+ . Herein, efficient Bi 2 Te 3 @C cathodes with an active carbon paper substrate are developed. Further ex situ characterization analysis confirms the energy storage mechanism regarding the coexistence of H + /Zn 2+ coinsertion and conversion reaction in the aqueous Zn||Bi 2 Te 3 @C battery. Benefiting from the fast dynamics process attributed to the unique mechanism, a reliable energy supply is provided even in an extended temperature range from −10 to 45 °C. More importantly, Bi 2 Te 3 @C cathodes boost the superior and repeatable air-rechargeability. A discharge capacity of up to 264.20 mA h g –1 at 0.30 A g –1 is manifested after self-charging for 11.00 h. In addition, two quasi-solid-state battery devices are connected in series to continuously power a timer. After the device is discharged and then air self-charged for just a few seconds, an LED is lit.