The ground state molecular structure, frontier molecular orbitals, energy levels, intramolecular charge transfer and absorption spectra of several newly synthesized solar-cell dye sensitizers are studied using density functional theory. The properties of these dye sensitizers are investigated under three different molecular states, protonated, deprotonated and adsorbed on (TiO2)10 cluster. Geometrical analysis summarizes the degree of conjugation of two aromatic rings such as triphenylamine, fluorene, thiophene, benzene and EDOT. Results show the thiophene and EDOT are more effective ?-conjugated spacers than benzene ring. Time-dependent density functional theory calculations show the simulated absorption spectra are excellent agreement with experimental spectra when the dye sensitizers are at their protonated states in solution. Upon adsorbing on TiO2 cluster, calculations as well as experiments show the absorption spectra are blue-shifted in relative to those in THF solution. These results are arisen from the de-conjugation of carboxylic groups when they are attached to (TiO2)10 cluster derived from geometrical analysis. The electron density difference analysis show the photoexcitation transfers the electron density on the electron-donating moiety to the acceptor/anchoring side allowing these dyes to be effective and potential in the dye-sensitized solar cell applications.