Litcius/Paper detail

Precipitate-stabilized surface enabling high-performance Na0.67Ni0.33-xMn0.67ZnxO2 for sodium-ion battery

Kuan Wang, Zhengfeng Zhang, Sulan Cheng, Xiao Han, Junjie Fu, Manling Sui, Pengfei Yan

2022eScience124 citationsDOIOpen Access PDF

Abstract

Electrode interfacial degradations are the key challenges for high-performance rechargeable batteries, usually mitigated through surface modification/coating strategies. Herein, we report a novel mechanism to enhance the surface stability of P2 layered cathodes by introducing a high density of dopant-enriched precipitates. Based on microscopic analysis, we show that forming a high density of precipitates at the grain surface can effectively suppress surface cracking and corrosion, which not only improves the surface/interface stability but also effectively suppresses the intergranular cracking issue. Increasing the doping level can lead to a greater density of precipitates at the surface region, which results in higher surface stability and increased cycling stability of the P2 layered cathode for a sodium-ion battery. We further reveal that prolonged cycling can induce the formation of a precipitate-free surface region due to the loss of Zn dopant and Na. Our in-depth microanalysis reveals cycling-induced dynamic structural evolution of the P2 layered cathodes, highlighting that dopant segregation-induced precipitation is a new approach to achieving high interfacial stability.

Topics & Concepts

Materials scienceDopantCathodeIntergranular corrosionPrecipitationChemical engineeringCoatingBattery (electricity)DopingSurface modificationIonMetallurgyCorrosionComposite materialOptoelectronicsChemistryPower (physics)Organic chemistryEngineeringPhysical chemistryMeteorologyQuantum mechanicsPhysicsAdvancements in Battery MaterialsAdvanced Battery Technologies ResearchAdvanced battery technologies research