Modifying Surface Chemistry to Enhance the Electrochemical Stability of Nickel-Rich Cathode Materials

Residual impurities such as lithium carbonate and hydroxide are a major concern for accelerating parasitic reactions at the cathode electrolyte interface of lithium-ion batteries. Removal of these lithium-bearing species becomes a necessity for high-performance nickel-rich cathode materials. Instead of directly removing these impurities through washing steps, a wet impregnation process is employed to convert these detrimental surface impurities into beneficial surface coating on nickel-rich cathode materials. Specifically, the pristine cathode material is treated with Al(H2PO4)3 solution to convert undesired compounds into Li3PO4 and AlPO4, both of which are considered positive surface coating materials for high-voltage cathodes. It is found that the introduced modification greatly suppresses the interfacial impedance hike and improves the capacity retention of the cathode material after repeating charging/discharging. It is believed that these benefits are realized through the modification of the surface chemistry of the cathode material, which helps to slow down the parasitic reactions and reduce the damage to the cathode material. To mitigate parasitic reactions at the cathode electrolyte interface in lithium-ion batteries, residual impurities like Li2CO3 and LiOH pose a significant challenge. Rather than traditional washing, a wet impregnation method is employed to transform these impurities into beneficial surface coatings on nickel-rich cathode materials, enhancing performance by reducing interfacial impedance and improving capacity retention through surface chemistry modification.image