Revolutionizing Ni-rich Cathode Durability! #researchaward


The electrochemical durability of Ni-rich cathodes remains a critical challenge in lithium-ion battery technology. This study introduces a thermodynamics-directed bulk and grain-boundary engineering approach to enhance their stability and longevity. By optimizing the cathode's microstructure, we mitigate phase transitions, suppress crack propagation, and reduce side reactions with the electrolyte. This method significantly improves capacity retention and cycling performance, addressing the degradation issues of high-Ni cathodes. Our findings provide a pathway toward more reliable and high-energy-density batteries, paving the way for next-generation energy storage solutions with superior efficiency and extended lifespan.

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#BatteryTech #EnergyStorage #LithiumIon #CathodeEngineering #NiRichCathode #Electrochemistry #BatteryInnovation #MaterialScience #SustainableEnergy #EnergyDensity #Thermodynamics #GrainBoundary #BatteryDurability #EVBatteries #BatteryMaterials #CleanEnergy #BatteryPerformance #NextGenBatteries #RenewableEnergy #ElectrodeDesign

 

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