The ability of ceria to break H 2 in the absence of noble metals has prompted a number of studies because of its potential applications in many technological fields. Most of the theoretical works reported in the literature are focused on the most stable (111) termination. However, recently, the possibility of stabilizing ceria particles with selected terminations has opened new avenues to explore. In the present paper, we investigate the role of termination in H 2 dissociation on stoichiometric ceria. We model (111)-, (110)-, and (100)-terminated slabs together with the stepped (221) and (331) surfaces. Our results support a dissociation mechanism proceeding via the formation of a hydride/hydroxyl CeH/OH intermediate. Both the stability of such an intermediate and the activation energy depend critically on the termination, the (100)-terminated surfaces being the most reactive: the activation energy is 0.16 eV, and the CeH/OH intermediate is stable by −0.64 eV for the (100) slab, whereas the (111) slab presents 0.75 and 0.74 eV, respectively. We provide structural, energetic, electronic, and spectroscopic data, as well as chemical descriptors correlating structure, energy, and reactivity, to guide in the theoretical and experimental characterization of the Ce–H surface intermediate.
A four-step reaction mechanism is proposed for the H 2 dissociation over pure ceria and galliumpromoted mixed oxide materials, in a combined experimental and computational investigation. Two samples of cerium-gallium mixed oxides with Ce/Ga atomic ratios equal to 90/10 and 80/20 were studied by time-resolved diffuse reflectance infrared spectroscopy under H 2 (D 2) flow at isothermal condition in the range of 523-623 K. X-ray photoelectron spectrometry allowed to conclude that only Ce 4+ is reduced to Ce 3+ (Ga 3+ is not reduced), in agreement with density functional theory (DFT) results. The time evolution profiles of gallium hydride ðGaAHÞ species, hydroxyl groups (OH) and Ce 3+ infrared signals were analyzed and kinetic rate parameters for each step were obtained by mathematical modeling. The values for activation energies were in agreement with those calculated by DFT, for the different elementary pathways. A small activation energy ($4 kcal/mol) was found for H 2 dissociation found on Ga Á Á Á OACe sites assuming that the heterolytic cleavage of the HAH bond is the rate determining step. On pure ceria, the experimental activation energy is $23 kcal/mol, showing that the addition of Ga 3+ cations boosts the splitting of H 2. Interestingly, the reduction step of pure CeO 2 surface domains seems to proceed via a CeH/OH pair intermediate, according to DFT calculations. Moreover, 71 Ga NMR experiments indicate the possible presence of gallia nanodomains. It is proposed that the generation of Ga Á Á Á OACe sites in the perimeter of such surface gallia nanodomains is responsible for the enhanced reactivity of the mixed materials. The key role of this new type of sites to improve the efficiency of relevant catalytic reactions such as selective alkyne hydrogenation and light alkane dehydrogenation is then analyzed. q This contribution is part of the virtual issue ''30 years of the International Conferences on Theoretical Aspects of Catalysis (ICTAC)".
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