In this study, newly designed cathode material LiFeP1-xSixO4, with silicon mixed in LiFePO4 is investigated using the density functional theory. Its most optimized structure is the olivine structure of the Pnma space group. Bonding length show the anti-site defect which hinders Li diffusivity is prevented in the LiFeP1-xSixO4. Lithium migration energy barriers in the (010) path of LiFeP1-xSixO4 (x=0, 0.5, and 1) are calculated by using nudged elastic band calculations, and the average values are determined as 0.180, 0.245, and 0.280 eV for LiFePO4, LiFeP1-xSixO4, and LiFeSiO4, respectively. This signifies that the Li ionic diffusivity is degraded thermodynamically, which is contrary to that indicates by the calculated bonding length, however, the difference is negligibly small. Furthermore, the intercalation voltage increases up to 4.97 V, depending on the Si ratio to P, and is much higher than that of the pristine cathode materials LiFePO4 (similar to 3.47 V) enabling voltage optimization by Si substitution. The energy density is proportional to the intercalation voltage, hence the energy density is increased, respectively. Finally, the Total density of states show that the electronic conductivity of LiFeP1-xSixO4 (x 0-1) is better than that of LiFePO4. (C) 2019 Published by Elsevier Ltd.