An atomic force microscopy (AFM) and confocal Raman microscopy Study of the interfacial electron transfer of a dye-sensitization system, i.e., alizarin adsorbed upon TiO2, nanoparticles. has revealed the distribution of the mode-specific vibrational reorganization energies encompassing different local sites (similar to 250-nm spatial resolution). Our experimental results suggest inhomogeneous vibrational reorganization energy barriers and different Franck-Condon coupling factors of the interfacial electron transfer. The total vibrational reorganization energy was inhomogeneous from site to site, specifically, mode-specific analyses indicated that energy distributions were inhomogeneous for bridging normal modes and less inhomogeneous or homogeneous for nonbridging normal modes, especially for modes far away from the alizarin-TiO2 coupling hydroxyl modes. The results demonstrate a significant step forward in characterizing site-specific inhomogeneous interfacial charge-transfer dynamics.