Abstract

The layered lithium-rich cathode material, Li_1.2Ni_0.2Mn_0.6O₂, was successfully synthesized by a sol-gel method followed by coating with different amounts of Li₂O-2B₂O (LBO, 1, 3, and 5 wt %). The effects of LBO-coating layer on the structure, morphology, and low-temperature (-30 °C) electrochemical properties of these materials are investigated systematically. The morphology, crystal structure, and grain size of the Li-rich layered oxide are not essentially changed after surface modification; according to the TEM results, the Li-B-O coating layer exists as an amorphous layer with a thickness of 5-8 nm when the amount is 3 wt %. Electrochemistry tests reveal that 3 wt % LBO-coated samples present the best electrochemical capability at low temperature. At -20 °C, the 3 wt % LBO-coated sample could retain 45.7% of the initial discharge capacity (131.7/288.0 mAh g^-1) of that at 30 °C, while the pristine material could only retain 22.5% (57.5/256.0 mAh g^-1). XPS spectra and EIS results reveal that such an enhancement of low-temperature discharge capacity should be attributed to the proper LBO-coating layer, which not only endows the modified materials with more stable surface structure but also lowers the interface resistance of Li⁺ diffusion through the interface and charge transfer reaction.