Enhanced Electrochemical Performance of Ni-Rich Cathode Materials with an In Situ-Formed LiBO2/B2O3 Hybrid Coating Layer
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Abstract
Surface Li residues on Ni-rich cathode materials lead to adverse interfacial side reactions, which in turn gives rise to rapid structural and capacity degradations during long-term cycling. Washing is a direct and effective method to remove the residual Li compounds but tends to change the surface structure of the Ni-rich cathode, increasing its air sensitivity. Herein, we report a facile single-step method to prepare an in situ-formed LiBO2/B2O3 hybrid coating layer on the surface of LiNi0.8Co0.1Mn0.1O2. The fast ion conductor, LiBO2, is generated via the consumption of surface Li impurities by H3BO3, forming a hybrid coating layer together with the cogenerated B2O3. Such an optimized hybrid coating layer combines the functions of removing surface Li residues, promoting Li+-ion transport, and isolating the cathode material and electrolyte, resulting in a modified Ni-rich cathode material that exhibits superior cycling stability and rate capability compared with the unmodified Ni-rich cathode material. The results demonstrate the feasibility of this hybrid coating strategy to remove the surface Li residues without adversely affecting the performance of Ni-rich cathode materials.
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