Thermal stability of ruthenium (II) complexes of the type [Ru(H(2)dcbpy)(2)(NCs)(2)] 1, (Bu4N)(2)[Ru(Hdcbpy)(2)(NCS)(2)] 2, (Bu4N)(4) [Ru(dcbpy)(2)(NCS)(2)] 3, and (Im)(4)[Ru(dcbpy)(2)(NCS)(2)] 4, where dcbpy=2, 2'-bipyridyl-4,4'dicarboxylate, Bu4N+=tetrabutylammonium, and Im=dimethylethylimidazolium, has been studied using thermoanalytical techniques, IR, UV-VIS, and H-1 NMR spectroscopic methods. These complexes show remarkable stability in both nitrogen and air atmospheres at high temperatures, ranging from 180 degrees C for 2 to 250 degrees C for 1. The only process that is observed at lower temperatures is the dehydration which occurs between 40 and 110 degrees C. High temperature processes including deamination of the counterion as well as decarboxylation and decomposition of the complex occur between 200 and 400 degrees C with different characteristics in air and in nitrogen. The decarboxylation reaction is an endothermic process in nitrogen atmosphere and overlaps with decomposition of the complexes. In air, on the other hand, it is an exothermic process distinctively separated from decomposition. Higher thermal stability is observed for 1 and 2 when anchored onto nanocrystaline TiO2 films. The activation energy of decarboxylation is estimated for 1 in the free form (ca, 103 kJ mol(-1)) and on TiO2 (ca. 126 kJ mol(-1)).