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Correlating Rate‐Dependent Transition Metal Dissolution between Structure Degradation in Li‐Rich Layered Oxides

Bo Cao, Tianyi Li, Wenguang Zhao, Liang Yin, Hongbin Cao, Dong Chen, Luxi Li, Feng Pan, Ming‐Jian Zhang

2023Small34 citationsDOIOpen Access PDF

Abstract

Abstract Understanding the mechanism of the rate‐dependent electrochemical performance degradation in cathodes is crucial to developing fast charging/discharging cathodes for Li‐ion batteries. Here, taking Li‐rich layered oxide Li 1.2 Ni 0.13 Co 0.13 Mn 0.54 O 2 as the model cathode, the mechanisms of performance degradation at low and high rates are comparatively investigated from two aspects, the transition metal (TM) dissolution and the structure change. Quantitative analyses combining spatial‐resolved synchrotron X‐ray fluorescence (XRF) imaging, synchrotron X–ray diffraction (XRD) and transmission electron microscopy (TEM) techniques reveal that low‐rate cycling leads to gradient TM dissolution and severe bulk structure degradation within the individual secondary particles, and especially the latter causes lots of microcracks within secondary particles, and becomes the main reason for the fast capacity and voltage decay. In contrast, high‐rate cycling leads to more TM dissolution than low‐rate cycling, which concentrates at the particle surface and directly induces the more severe surface structure degradation to the electrochemically inactive rock‐salt phase, eventually causing a faster capacity and voltage decay than low‐rate cycling. These findings highlight the protection of the surface structure for developing fast charging/discharging cathodes for Li‐ion batteries.

Topics & Concepts

DissolutionMaterials scienceCathodeDegradation (telecommunications)ElectrochemistrySynchrotronTransmission electron microscopyOxideChemical engineeringTransition metalIonScanning transmission electron microscopyAnalytical Chemistry (journal)NanotechnologyMetallurgyElectrodeChemistryOpticsPhysical chemistryOrganic chemistryPhysicsChromatographyEngineeringComputer scienceBiochemistryTelecommunicationsCatalysisAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesExtraction and Separation Processes