In this thesis, the broadband and omnidirectional light-trapping scheme employing microscale and nanoscale structures are introduced to Si heterojunction solar cells for boosting the photovoltaic performances, and the optical and carrier recombination characteristics of the devices are discussed in detail. In the first part, hierarchical structures consisting of grooves and pyramids are demonstrated in a-Si/c-Si heterojunction solar cells via isotropic etching followed by anisotropic etching. The structure combines the excellent photo managements and creation of long-lived minority carriers into the solar cells, showing an improved conversion efficiency of 15.2%, an open-circuit voltage of 607 mV, and a short-circuit current density of 36.4 mA/cm2. With the superior omnidirectionality, the enhancement of power generation is up to 92% at high incident angles. Such fabrication approach of hierarchical structures open new avenues for various Si-based solar cells with improved conversion efficiency by effective light harvesting. In the second part, semiconductor-insulator-semiconductor solar cells based on IZO/SiO2/Si can be achieved to the conversion efficiency of 7.01% with a VOC of 430 mV and a JSC of 28 mA/cm2 owing to the optimal SiO 2 layer by 5 minutes hot H2O treatment. In addition, the employment of ZnO Nanorods on IZO/Si heterojunction can improves the Jsc from 28.0 to 30.8 mA/cm2 and the efficiency from 7.01% to 7.51 % due to superior light trapping ability.