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Interfacial modulation engineering for sodium layered oxide cathode: air stability, ion-transfer kinetics, and phase evolution

06.29.25 | Science China Press

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Interfacial Modulation Engineering for Sodium Layered Oxide Cathode: Air Stability, Ion-Transfer Kinetics, and Phase Evolution
The main challenges faced by NaxTMO2cathodes and the interfacial reconstruction strategies such as organic/inorganic coating as well as corresponding surface structure enhancement mechanisms are discussed in depth. Credit: ©Science China Press

Sodium-ion batteries (SIBs) have garnered significant attentions for grid-scale energy storage due to the low cost and abundant sodium resources. Among the various cathode materials, sodium layered transition metal oxides (Na x TMO 2 ) are considered highly promising for practical applications of SIBs relying on their high theoretical capacities and facile syntheses. However, the poor air stability, sluggish interfacial kinetics, and detrimental phase transitions of Na x TMO 2 commonly result in unsatisfactory cycling stability as well as inferior rate capability.

Now, in a recent review published in SCIENCE CHINA Chemistry , led by Professor Yao Xiao from the College of Chemistry and Materials Engineering at Wenzhou University. T “The recent achievements and progress in interfacial regulations aimed at improving the air stability and electrochemical performances of Na x TMO 2 , such as organic/inorganic coating, interfacial-coating-doping, and heterogeneous phase designing are summarized. These approaches can not only enable the in-situ conversion of residual alkali and/or enhance the interfacial stability, but also improve the electrochemical reaction kinetics and mitigate phase evolutions. The structural stability enhancement mechanisms of Na x TMO 2 resulted from surface reconstructions are profoundly discussed and the influences on their electrochemical properties are concluded in this work. Finally, the novel interfacial modification strategies like of layered-tunnel heterostructure building and organic-inorganic co-coating were emphasized. The state-of-the-art characterization techniques and artificial intelligence are also elaborated to develop high-performance Na x TMO 2 cathodes in the future. “We believe that the insights presented in this review can serve as meaningful guidance for the interfacial modulations of Na x TMO 2 cathodes.” Xiao says.

See the article:

Interfacial Modulation Engineering for Sodium Layered Oxide Cathode: Air Stability, Ion-Transfer Kinetics, and Phase Evolution

https://doi.org/10.1007/s11426-024-2725-6

Science China Chemistry

10.1007/s11426-024-2725-6

Keywords

Applied Sciences and Engineering Physical Sciences

Article Information

Journal
Science China Chemistry
DOI
10.1007/s11426-024-2725-6

Contact Information

Bei Yan
Science China Press
yanbei@scichina.com

How to Cite This Article

APA:
Science China Press. (2025, June 29). Interfacial modulation engineering for sodium layered oxide cathode: air stability, ion-transfer kinetics, and phase evolution. Brightsurf News. https://www.brightsurf.com/news/LKN0J6GL/interfacial-modulation-engineering-for-sodium-layered-oxide-cathode-air-stability-ion-transfer-kinetics-and-phase-evolution.html
MLA:
"Interfacial modulation engineering for sodium layered oxide cathode: air stability, ion-transfer kinetics, and phase evolution." Brightsurf News, Jun. 29 2025, https://www.brightsurf.com/news/LKN0J6GL/interfacial-modulation-engineering-for-sodium-layered-oxide-cathode-air-stability-ion-transfer-kinetics-and-phase-evolution.html.