Modification strategy for advanced Mn-based layered transition metal oxide cathode for sodium-ion batteries

Ka Ho Wong, Maiwen Zhang, Tingzhou Yang, Qianyi Ma, Shuqi Dai, Jing Wei, Ganesh Kuma, Ali Abdulkareem AlHammadi, Georgios Karanikolos, Elena Bekyarova, Ali Elkamel, Aiping Yu

    Research output: Contribution to journalReview articlepeer-review

    Abstract

    Sodium-ion batteries (SIBs) are being touted as the future of energy storage. However, the lackluster performance of current cathode technology is a major roadblock to their widespread use. Among the promising candidates for cathodes, layered sodium manganese oxide stands out due to its low cost and higher energy density. However, its cycling performance is limited due to structural and surface instabilities. To overcome these challenges, researchers are exploring various strategies, such as doping, coating, and heterostructure design, to enhance the performance of manganese-based oxide. Doping involves introducing foreign atoms to enhance structural stability and electrochemical performance. Coating is a surface protection method, while heterostructure design involves developing a composite material composed of different crystal phases of sodium manganese oxide to leverage the intrinsic advantage of each phase. This review introduces the existing challenges of layered sodium manganese oxide and provides a comprehensive understanding of reported strategies and their potential for improving the performance of this material. By analyzing the latest research, we hope to contribute to the development of practical and scalable SIBs.

    Original languageBritish English
    Article number103549
    JournalEnergy Storage Materials
    Volume71
    DOIs
    StatePublished - Aug 2024

    Keywords

    • Layered sodium manganese oxide
    • Modification strategies
    • Sodium-ion batteries

    Fingerprint

    Dive into the research topics of 'Modification strategy for advanced Mn-based layered transition metal oxide cathode for sodium-ion batteries'. Together they form a unique fingerprint.

    Cite this