In this thesis, we used a hydrothermal method to synthesize ultra-long ZnO nanorods array (NRA), which was utilized as the effective anti-reflective structure for enhancing the performance of silicon solar cells.We investigated the effect of precursor concentration on the characteristics of broadband anti-reflection as well as the efficiency of silicon solar cells. After the thermal treatment, a significant change in the photoluminescence spectra from ZnO NRA was observed. The deep-level emission was suppressed due to the removal of the intrinsic defect by the thermal treatment. Therefore, the sunlight can pass through the anti-reflective structure rather than be absorbed by the ZnO NRA. Finally, atomic layer deposition was used to deposit highly conformal Al 2 O 3 layer on the surface of ZnO NRA to further reduce reflectance and provide effective protection of the chemically fragile ZnO NRA from harmful environments. The thickness of the Al 2 O 3 layer for minimum reflectance was examined experimentally, which is in good agreement with the result obtained from the finite-different time-domain (FTDT) simulation. . Under the optimal precursor concentration and the thickness of conformal Al 2 O 3 layer, the efficiency of silicon solar cells could be greatly improved from 9.08% to 18.28% by using the ZnO NRA as the anti-reflective structure. The result indicates that the ZnO/Al 2 O 3 core-shell NRA is a very promising anti-reflective structure for effective enhancement of the performance of solar cells and other photonic devices.