H 2 production over dye-sensitized Pt/TiO 2 nanoparticles with mesostructures (m-TiO 2 ) under visible light (ฮป > 420 nm) was investigated by using methanol as electron donors. Experimental results indicate that three types of ruthenium(II) bipyridyl complex dyes (one binuclear Ru, two mononuclear Ru), which can be attached to Pt/m-TiO 2 with different linkage modes, show different photosensitization effects due to their different coordination circumstances and physicochemical properties. The dye tightly linked with m-TiO 2 has better durability but the lowest H 2 evolution efficiency, whereas the loosely attached dyes possess higher H 2 evolution efficiency and preferable durability. It seems that the dynamic equilibrium between the linkage of the ground state dye with TiO 2 and the divorce of the oxidization state dye from the surfaces plays a crucial role in the photochemical behavior during the photocatalyst sensitization process. It is helpful to improve the H 2 evolution efficiency by enhancing the electron injection and hindering the backward transfer. The binuclear Ru(II) dye shows a better photosensitization in comparison with mononuclear Ru(II) dyes due to its large molecular area, conjugation system, and "antenna effect", which, in turn, improve the visible light harvesting and electron transfer between the dye molecules and TiO 2 .