Details

Autor(en) / Beteiligte

• Zhao, Wentian
• Yang, Yong
• Deng, Qinghua
• Dai, Qingyang
• Fang, Zhao
• Fu, Xiaolong
• Yan, Wuwei
• Wu, Lizhi
• Zhou, Yong

Titel

Toward an Understanding of Bimetallic MXene Solid‐Solution in Binder‐Free Electrocatalyst Cathode for Advanced Li–CO2 Batteries

Ist Teil von

• Advanced functional materials, 2023-01, Vol.33 (5), p.n/a

Ort / Verlag

Hoboken: Wiley Subscription Services, Inc

Erscheinungsjahr

2023

Link zum Volltext

Quelle

Wiley Blackwell Single Titles

Beschreibungen/Notizen

• Li–CO2 batteries have received extensive attention due to their high energy storage capacity and utilization of CO2 resources. Herein, bimetallic MXene solid‐solution TiVC is prepared and combined with highly conductive graphene for the construction of binder‐free electrocatalyst cathodes for Li–CO2 batteries. Considering the electronic structure, the unique synergy effect between Ti and V in TiVC enhances the interfacial chemical bonding ability, facilitates sufficient exposure of active sites and promotes catalytic interfacial structural reformation, thereby promoting the reversible formation and decomposition of the chemically inert discharge product Li2CO3. Meanwhile, the abundant pores and excellent electron transfer ability of graphene aerogel are conducive to the gas diffusion and ion transport, thus reducing the mass and charge transfer resistance. As a result, the assembled Li–CO2 battery presents an excellent discharge capacity of 27 880 mAh g−1 with a stable discharge plateau of 2.77 V and low overpotential of 1.5 V based on the TiVC‐graphene aerogel electrocatalytic cathode. The density functional theory calculations are further performed to deeply reveal the unique electronic structure information between Ti and V in the solid‐solution TiVC. This study provides inspiration for exploring more bimetallic MXene solid solutions and developing advanced cathode catalysts for flexible Li–CO2 batteries. Bimetallic MXene solid‐solution TiVC is prepared and combined with highly conductive graphene for the construction of advanced binder‐free electrocatalyst cathodes for Li–CO2 batteries. The density functional theory calculations combined with experimental investigations deeply reveal the unique electronic structure information between Ti and V in the solid‐solution TiVC, which contributes to the superior performances of the assembled Li–CO2 battery.