Rational Design of Nanostructured Metal/C Interface in 3D Self‐Supporting Cellulose Carbon Aerogel Facilitating High‐Performance Li‐CO 2 Batteries

The sluggish kinetics of CO 2 reduction and evolution reaction (CRR and CER) on the Li–CO 2 battery cathode seriously hindered its practical application. Rational design of the Ru/C interface is expected to simultaneously decrease the free energy barrier of intermediate species and create a favorabl...

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Bibliographic Details
Published in:Advanced energy materials 2022-05, Vol.12 (20)
Main Authors: Liu, Limin, Qin, Yanyang, Wang, Ke, Mao, Heng, Wu, Hu, Yu, Wei, Zhang, Dongyang, Zhao, Hongyang, Wang, Hairong, Wang, Jiuhong, Xiao, Chunhui, Su, Yaqiong, Ding, Shujiang
Format: Article
Language:English
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Summary:The sluggish kinetics of CO 2 reduction and evolution reaction (CRR and CER) on the Li–CO 2 battery cathode seriously hindered its practical application. Rational design of the Ru/C interface is expected to simultaneously decrease the free energy barrier of intermediate species and create a favorable electronic structure, effectively promoting the catalytic reaction kinetics of the CRR and CER. Herein, a 3D self‐supporting cellulose carbon aerogel (CCA) with well‐defined Ru/C interfaces (Ru@CCA) is synthesized as an advanced CO 2 ‐breathing cathode for Li–CO 2 batteries. The results show that the energy efficiency significantly improves to 80% with a high discharge capacity of 10.71 mA h cm −2 at 20 µA cm −2 , and excellent cyclic stability of 421 cycles at 100 µA cm −2 . These outstanding performances are highly competitive compared with state‐of‐art Li–CO 2 cathodes. In addition, the unique interface design strategy is applied to other non‐noble metal@CCA cathodes, which confirms the advantages of constructing nanostructure metal/C interfaces for improving the kinetics of CRR and CER. This fundamental understanding of the structure–performance relationship provides new inspiration for designing highly efficient cathode catalysts for Li–CO 2 batteries.
ISSN:1614-6832
1614-6840
DOI:10.1002/aenm.202103681