Abstract

The spinel NiFe2O4 widely used as anode active material for lithium ion batteries (LIBs) was prepared as a coating layer on LiMn2O4 particles via a sol–gel route followed by heat treatment. The effect of the surface modification on the electrochemical performances of the cathode material was investigated both in LiMn2O4∥Li and LiMn2O4∥graphite batteries. The well-crystallized NiFe2O4 coating layer shows a continuous and uniform film with a thickness of 10–11 nm on the surface of the LiMn2O4 material. The as-prepared LiMn2O4/NiFe2O4 composite with a coating amount of 1% shows an improved rate performance due to the high activity of the coating material. At an elevated temperatures of 55 °C, the initial discharge capacity at 0.1 C is 130.8 mAh/g, and the capacity retention is 84.5% after 400 cycles at 1 C when it is tested in a LiMn2O4∥Li cell, while a full battery with the modified LiMn2O4∥graphite as cathode material shows a capacity retention of 89.1% after 500 cycles. The enhanced cyclic performance can be attributed to the good physical properties of mechanical strength and thermal stability from NiFe2O4 material. The rate performance is also improved due to the higher Li cyclability of the coating layer, which has been proven by the CV and EIS tests. The inherent advantages of natural abundance, ecofriendliness, and low cost make it practical for large-scale modification of the relevant electrode materials which are attacked by electrolyte when charged to high potentials and similarly could benefit from surface stabilization.