In this thesis, we present photovoltaic results for various porphyrin molecules as potential sensitizers for dye-sensitized solar cells (DSSC). A new concept to design a zinc porphyrin sensitizer with two phenyl groups at meso -positions of the macrocycle bearing two ortho-substituted long alkoxyl chains is intorduced to protect the porphyrin core for a retarded charge recombination and also to decrease effectively the dye aggregation for an efficient electron injection. In the present work, such a molecular design was applied for a push–pull porphyrin (LD14) which is synthesized by Prof. C. Y. Lin of NCNU to attain an exceptional cell performance,  = 10.2 %. In the second part of this thesis, we present a rational design of two co- sensitization systems using two (LD12 and CD5) or three dyes (YD2-o-C8, CD4 and YDD6), for which the co-sensitized dyes have complementary adsorption spectra, to improve the device performance for porphyrin-sensitized solar cells. Upon optimization, the device made of LD12+CD5 yielded ƞ = 9.0%. We found that CD5 plays a role to retard charge recombination efficiently based on the results obtained from intensity-modulated photovoltage spectral measurement. In order to further enhance the light-harvesting ability, we use the near-infrared dye YDD6, synthesized by C. Y. Yeh of NCHN, co-sensitized with YD2-o-C8 and CD4. After well controlled the amounts of dye loading for these three dyes, we are able to optimize the device made of the YD2-o-C8/CD4/YDD6 system yielding ƞ =10.3 %.