Multidimensional Nonstoichiometric Electrode Materials for Electrochemical Energy Conversion and Storage

Nonstoichiometry plays an important role in determining physicochemical properties such as conductivity, activity, and stability due to the composition‐induced change in phase, local atomic environment, and electronic structure. A variety of materials with nonstoichiometry have emerged in electroche...

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Bibliographic Details
Published in:Advanced energy materials 2022-01, Vol.12 (4), p.n/a
Main Authors: Yu, Meng, Liu, Fangming, Li, Jinhan, Liu, Jiuding, Zhang, Yudong, Cheng, Fangyi
Format: Article
Language:English
Subjects:
electrocatalysis
Electrode materials
Electronic structure
Energy conversion
Energy storage
Hydrogen evolution
metal‐ion batteries
nonstoichiometric electrode materials
nonstoichiometry
Reduction
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Summary:Nonstoichiometry plays an important role in determining physicochemical properties such as conductivity, activity, and stability due to the composition‐induced change in phase, local atomic environment, and electronic structure. A variety of materials with nonstoichiometry have emerged in electrochemical energy conversion and storage, which necessitates a solid understanding of their formation mechanism and structure–function relationship. This review presents a summary of the progress made in this emerging field, starting from the introduction of the multiscale top‐down and bottom‐up strategies for generating nonstoichiometry and the related characterization methodologies. Then, representative nonstoichiometric materials (NMs) are discussed in properties and merits, with selected examples of each material category. A special focus is placed on the dimensionality from atomic sites to surface/interfaces, grains, microstructure, and hierarchical macroscale. After that, recent advances are overviewed for the use of exemplified NMs in electrocatalysis (i.e., oxygen reduction/evolution, hydrogen evolution, and nitrogen reduction) and batteries (i.e., Li/Na/Zn batteries). The review is concluded with a summary highlighting the beneficial effects of NMs and a perspective on further research to address remaining issues. Nonstoichiometric materials are widely employed for electrochemical energy conversion and storage due to composition‐induced variation in phase, local atomic environment, electronic structure, and charge transportation. This review summarizes the physiochemical properties, synthesis, characterization techniques, and the typical application of nonstoichiometric electrode materials in electrocatalysis and rechargeable batteries, highlighting multidimensional information gained from microstructure to macroscale.
ISSN:1614-6832
1614-6840
DOI:10.1002/aenm.202100640