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Enhancing the long-term cycling stability of Ni-rich cathodes via regulating the length/width ratio of primary particle

Duzhao Han, Jilu Zhang, Mingyu Yang, Keyu Xie, Jiali Peng, Oleksandr Dolotko, Cheng Huang, Yuping Wu, Shao Le, Weibo Hua, Wei Tang

2024Energy Materials19 citationsDOIOpen Access PDF

Abstract

Ni-rich layered oxide cathode materials are promising candidates for high-specific-energy battery systems owing to their high reversible capacity. However, their widespread application is still severely impeded by severe capacity loss upon long-term cycling. It has been proven that the cyclic stability of Ni-rich cathode materials is closely related to their microstructure and morphology. Despite this, the influence of the microstructure of primary particles on the fatigue mechanism of Ni-rich cathode materials during prolonged cycling has not been fully understood. Here, two Ni-rich layered spherical agglomerate oxides consisting of the primary particle with different length/width ratios are successfully synthesized. It is found that the long-term structural stability of both materials strongly depends on the microstructure of primary crystallites, although there is no significant difference between the electrochemical and crystalline characteristics during the initial cycle. A higher primary particle length/width ratio could effectively inhibit the accumulation of microcracks and chemical degradation during long-term cycling, thereby promoting the electrochemical performance of the cathode materials (80% capacity retention after 200 cycles at 1 C compared to the 55% of the counterpart with a lower primary particle length/width ratio). This study highlights the structure-activity relationship between the primary particle microstructure and fatigue mechanisms during long-term cycling, thereby advancing the development of Ni-rich cathode materials.

Topics & Concepts

MicrostructureCathodeMaterials scienceCyclingAgglomerateParticle (ecology)ElectrochemistryOxideComposite materialBattery (electricity)Chemical engineeringCrystalliteParticle sizeDegradation (telecommunications)MetallurgyElectrodeChemistryElectrical engineeringGeologyEngineeringPhysical chemistryArchaeologyPhysicsPower (physics)HistoryOceanographyQuantum mechanicsAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies Research