Photoinduced activation of CO2 on TiO2 surfaces: Quantum chemical modeling of CO2 adsorption on oxygen vacancies

Chemical processes that utilize CO₂ emissions from coal-fired power plants will be required as the world progresses towards reducing CO₂ emissions. The conversion of CO₂ using light energy (CO₂ photoreduction) has the potential to produce useful fuels or valuable chemicals while decreasing CO₂ emissions from the use of fossil fuels such as coal. Computational studies on the initial steps of photoinduced CO₂ activation on TiO₂ surfaces, necessary to develop a mechanistic understanding of CO₂ photoreduction are a focus of this article.The results from previous quantum mechanical modeling studies conducted by the authors indicated that stoichiometric TiO₂ surfaces likely do not promote electron transfer to CO₂. Therefore, the role of oxygen vacancies in promoting the light-induced conversion of CO₂ (CO₂ photoreduction) on TiO₂ surfaces was examined in this study. Two different side-on bonded bent-CO₂ (bridging Ti-CO₂^δ•−-Ti species) were formed on the reduced rutile (110) and anatase (010), (001) surfaces, indicating charge transfer from the reduced surface to CO₂. Further steps in the photoexcitation of these bent-CO₂ species were investigated with density functional theory calculations. Consistent with CO₂ adsorption and photodesorption on other n-type metal oxides such as ZrO₂, the results suggest that the bent-CO₂ species do not gain further charge from the TiO₂ surface under illumination and are likely photodesorbed as neutral species. Additionally, although the formation of species such as CO and HCHO is thermodynamically possible, the energy needed to regenerate the oxygen vacancy on TiO₂ surfaces (~ 7 eV) is greater than that available through band-gap illumination (3.2 eV). Therefore, CO₂ reactions with water on irradiated anatase TiO₂ surfaces are likely to be stoichiometric.