Multifunctional Effect of Fe Substitution in Na Layered Cathode Materials for Enhanced Storage Stability.
Jehee ParkKyojin KuJihyeon GimSeoung-Bum SonHeonjae JeongLei ChengHakim IddirDewen HouHui Claire XiongYuzi LiuEungje LeeChristopher S JohnsonPublished in: ACS applied materials & interfaces (2023)
Developing stable cathode materials that are resistant to storage degradation is essential for practical development and industrial processing of Na-ion batteries as many sodium layered oxide materials are susceptible to hygroscopicity and instability upon exposure to ambient air. Among the various layered compounds, Fe-substituted O3-type Na(Ni 1/2 Mn 1/2 ) 1- x Fe x O 2 materials have emerged as a promising option for high-performance and low-cost cathodes. While previous reports have noted the decent air-storage stability of these materials, the role and origin of Fe substitution in improving storage stability remain unclear. In this study, we investigate the air-resistant effect of Fe substitution in O3-Na(Ni 1/2 Mn 1/2 ) 1- x Fe x O 2 cathode materials by performing systematic surface and structural characterizations. We find that the improved storage stability can be attributed to the multifunctional effect of Fe substitution, which forms a surface protective layer containing an Fe-incorporated spinel phase and decreases the thermodynamical driving force for bulk chemical sodium extraction. With these mechanisms, Fe-containing cathodes can suppress the cascades of cathode degradation processes and better retain the electrochemical performance after air storage.
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