In the last decade, silicon has attracted much attention because it has a high specific capacity (~3600 mAh/g) compared to graphite (372 mAh/g). However, silicon is known for its intrinsic low conductivity while possessing a dramatic volumetric variation during cycling, which results in structural instability and poor cyclability that hinders its commercial application. The main objective of this research is to explore new materials based on silicon for the lithium-ion battery. According to past investigations, Si-C composite materials are developed to overcome the inherent problems of silicon. But now, intrinsic silicon is further improved, increasing the surface area on the silicon surface. The preset intra-particle voids have been shown to help in accommodating volume expansion arising from the Si. The preparation of porous silicon applies etching technology used typically in semiconductor manufacturing as well as the use of an oxidizing agent and hydrofluoric acid solution. Results showed that this method produces many pores on the Silicon surface, and gave an outstanding performance of more than 100 cycles without fading under constant capacity (1000mAh/g) charge-discharge. This performance is a significant improvement over intrinsic Silicon and Carbon-coated intrinsic silicon in electrodes which only sustain less than 8 cycles and 80 cycles, respectively.