LiFexMn1-xPO4/C composites were synthesized by a solid-state reaction route using phenolic resin as both reducing agent and carbon source. The effect of Fe doping on the crystallinity and electrochemical performance of LiFexMn1-xPO4/C was investigated. The experimental results show that the Fe2+ substitution for Mn2+ will lead to crystal lattice shrinkage of LiFexMn1-xPO4/C particles due to the smaller ionic radii of Fe2+. In the investigated Fe doping range(x = 0 to 0.7), LiFexMn1-xPO4/C(x = 0.4) composites exhibited a maximum discharge capacity of 148.8 m Ah/g at 0.1 C while LiFexMn1-xPO4/C(x = 0.7) composite showed the best cycle capability with a capacity retention ratio of 99.0% after 30 cycles at 0.2 C. On the contrary, the LiFexMn1-xPO4/C(x = 0.5) composite performed better trade-off on discharge capacity and capacity retention ratio, 127.2 m Ah/g and 94.7% after the first 30 cycles at 0.2 C, respectively, which is more preferred for practical applications. LiFexMn1-xPO4 / C composites were synthesized by a solid-state reaction route using phenolic resin as both reducing agent and carbon source. The effect of Fe doping on the crystallinity and electrochemical performance of LiFexMn1-xPO4 / C was investigated. The experimental results show that the Fe2 + substitution for Mn2 + will lead to crystal lattice shrinkage of LiFexMn1-xPO4 / C particles due to the smaller ionic radii of Fe2 +. In the investigated Fe doping range (x = 0 to 0.7), LiFexMn1- 0.4) composites exhibited a maximum capacity of 148.8 m Ah / g at 0.1 C while LiFexMn1-x PO4 / C (x = 0.7) composite showed the best cycle capability with a capacity retention ratio of 99.0% after 30 cycles at 0.2 C. On the contrary, the LiFexMn1-xPO4 / C (x = 0.5) composite performed better trade-off on discharge capacity and capacity retention ratio, 127.2 m Ah / g and 94.7% after the first 30 cycles at 0.2 C, respectively, which is more preferred for practical applications.