The main purpose of this research is to explore new anode materials based on silicon for lithium-ion battery. Due to the high theoretical capacity of silicon (~3500 mAh/g), it has the potential to replace graphite (372 mAh/g) as anode materials. However, Si has the dramatic volumetric variation (400%) problem during cycling and its low conductivity. This limits the application in commercial. Si/C composite materials are prepared by two different methods to overcome the problems just mentioned. One is carbon coating on Si particle, and the other one is Electrospinning method to produce Si@C nanofiber structure. Carbon-coated Si materials have been prepared by thermal treatment in air atmosphere, and then put the composite to the quartz tube through calcination in inert gas at high temperature to form the homogeneous carbon layer onto the surface of Si particle. Research shows that the calcination process contributes to the significantly proved cycling performance. Si@C nanofiber with high specific surface area and its average diameter after calcination is about 200 nm have been prepared by Electrospinning process. During the cycling tests, it seems the Si@C nanofiber structure electrode is not stable while charging/discharging because of the bad connection of fibers and the severe exposedness of Si particle after calcination.