Rational design of layered oxide materials for sodium-ion batteries

Chenglong Zhao; Qidi Wang; Zhenpeng Yao; Jianlin Wang; Benjamín Sánchez-Lengeling; Feixiang Ding; Xingguo Qi; Yaxiang Lu; Marnix Wagemaker; null More Authors

doi:10.1126/science.aay9972

Rational design of layered oxide materials for sodium-ion batteries

Chenglong Zhao, Qidi Wang, Zhenpeng Yao, Jianlin Wang, Benjamín Sánchez-Lengeling, Feixiang Ding, Xingguo Qi, Yaxiang Lu, Marnix Wagemaker, More Authors

RST/Storage of Electrochemical Energy

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Abstract

Sodium-ion batteries have captured widespread attention for grid-scale energy storage owing to the natural abundance of sodium. The performance of such batteries is limited by available electrode materials, especially for sodium-ion layered oxides, motivating the exploration of high compositional diversity. How the composition determines the structural chemistry is decisive for the electrochemical performance but very challenging to predict, especially for complex compositions. We introduce the "cationic potential" that captures the key interactions of layered materials and makes it possible to predict the stacking structures. This is demonstrated through the rational design and preparation of layered electrode materials with improved performance. As the stacking structure determines the functional properties, this methodology offers a solution toward the design of alkali metal layered oxides.

Original language	English
Pages (from-to)	708-711
Journal	Science
Volume	370
Issue number	6517
DOIs	https://doi.org/10.1126/science.aay9972
Publication status	Published - 2020

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AU - Zhao, Chenglong

AU - Wang, Qidi

AU - Yao, Zhenpeng

AU - Wang, Jianlin

AU - Sánchez-Lengeling, Benjamín

AU - Ding, Feixiang

AU - Qi, Xingguo

AU - Lu, Yaxiang

AU - Wagemaker, Marnix

AU - More Authors, null

N1 - Accepted Author Manuscript

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Y1 - 2020

N2 - Sodium-ion batteries have captured widespread attention for grid-scale energy storage owing to the natural abundance of sodium. The performance of such batteries is limited by available electrode materials, especially for sodium-ion layered oxides, motivating the exploration of high compositional diversity. How the composition determines the structural chemistry is decisive for the electrochemical performance but very challenging to predict, especially for complex compositions. We introduce the "cationic potential" that captures the key interactions of layered materials and makes it possible to predict the stacking structures. This is demonstrated through the rational design and preparation of layered electrode materials with improved performance. As the stacking structure determines the functional properties, this methodology offers a solution toward the design of alkali metal layered oxides.

AB - Sodium-ion batteries have captured widespread attention for grid-scale energy storage owing to the natural abundance of sodium. The performance of such batteries is limited by available electrode materials, especially for sodium-ion layered oxides, motivating the exploration of high compositional diversity. How the composition determines the structural chemistry is decisive for the electrochemical performance but very challenging to predict, especially for complex compositions. We introduce the "cationic potential" that captures the key interactions of layered materials and makes it possible to predict the stacking structures. This is demonstrated through the rational design and preparation of layered electrode materials with improved performance. As the stacking structure determines the functional properties, this methodology offers a solution toward the design of alkali metal layered oxides.

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Rational design of layered oxide materials for sodium-ion batteries

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