With the fossil fuels are shortage day by day and the raised environmental consciousness, humans need anxiously power sources which are clean and environmental friendly and applicable to on renewable energy. Solar energy is inexhaustible, calm and environmental friendly in the power generation. Therefore, solar cell is thought as the most promising renewable energy. Nowadays, commercial cell usually use the random pyramid as an antireflective structure, but its antireflective performance is not very well. The improvement of antireflective performance for conventional solar cell is not easy to achieve. Therefore, this study presents the integration of photolithography and photo-assisted electrochemical etching (PAECE) to fabricate a black silicon macroporous arrays with a high aspect ratio on the surface of silicon wafer, it will improve antireflective performance significantly. Porous silicon (PS) was grown on the 525 um and 380 um thick silicon wafers. The black silicon are produced after PAECE under the etching time of 0.5 hr, 1 hr, 1.5 hr, and 2 hr, respectively. The macroporous arrays with low reflection in the 280-800 nm wavelength regimes can be easily achieved. The weighted mean reflectance of a blank silicon wafer is 37.35 % in the 280-800 nm wavelength regimes. Inverted pyramid arrays without PAECE can reduce the weighted mean reflectance to 6.2 %. Inverted pyramid arrays with 30 min PAECE reduce the weighted mean reflectance even to 1.05 % on the 525 um thick silicon wafer. Besides, after PAECE of 2 hrs can reduce the weighted mean reflectance to 0.81 %. Besides, if the thickness of silicon wafer is decreased to 380 um, the weighted mean reflectance after PAECE of 2 hrs process further reduce to 0.72 %. The novel structure of combining inverted pyramid, deep macroporous, micro-trench, random porous, and black porous membrane can be observed simultaneously. Such a compound antireflective structure proposed in this study has the advantage to enhance light trapping, increase the area of light absorption and P-N junction, and can be applied as an antireflective structure to single crystalline silicon solar cell to improve its performance of efficiency.