We systematically designed and synthesized two series of phosensitizers for dye-sensitized solar cell applications. Firstly, we prepared three porphyrin dyes with various alkoxyl chains, labelled as LD14, LD14-C8, and LD14-C4, in order to address the effect of alkoxyl lengths. LD14, LD14-C8, and LD14-C4 show nearly identical UV-vis and fluorescence emission spectra in THF. This indicates that the effect of the alkoxyl chains on UV-vis absorption and fluorescence emission spectra are very small. Based on the molecular simulations results, we demonstrated that suitable long alkoxyl chains are capable of wrapping the porphyrin core, thus resulting in decreased dye aggregation and improved photovoltaic performance. Secondly, we synthesized a series of organic dyes bearing various electron-withdrawing group for dye-sensitized solar cell applications. DOA-An-CNPE1 exhibits slight red shift in the UV-vis spectra, consistent with the more conjugated structure. The LUMO levels of these dyes were sufficiently higher than the conduction band of TiO2. The overall efficiencies of the devices show the trend of DOA-An-PE1 > DOA-An-1FPE1 > DOA-An-CNPE1 > DOA-An-2FPE1 > DOA-An-CF3PE1. DOA-An-PE1 shows the best performance η value 4.96%, approximately 64 % of that of N719.