Molecular-Level Understanding of CeO2 as a Catalyst for Partial Alkyne Hydrogenation

Image credit: Enrique Sahagún, Scixel jpccck
Image credit: Enrique Sahagún, Scixel.

Cover: published in The Journal of Physical Chemistry C by Rubén Pérez, IFIMAC researcher.

In this work, the unique catalytic properties of ceria for the partial hydrogenation of alkynes are examined for acetylene hydrogenation. This important research hask been awarded the cover of The Journal of Physical Chemistry C.

The unique catalytic properties of ceria for the partial hydrogenation of alkynes are examined for acetylene hydrogenation. Catalytic tests over polycrystalline CeO2 at different temperatures and H2/C2H2 ratios reveal ethylene selectivities in the range of 75–85% at high degrees of acetylene conversion and hint at the crucial role of hydrogen dissociation on the overall process. Density-functional theory is applied to CeO2(111) in order to investigate reaction intermediates and to calculate the enthalpy and energy barrier for each elementary step, taking into account different adsorption geometries and the presence of potential isomers of the intermediates. At a high hydrogen coverage, β-C2H2 radicals adsorbed on-top of surface oxygen atoms are the initial reactive species forming C2H3 species effectively barrierless. The high alkene selectivity is owed to the lower activation barrier for subsequent hydrogenation leading to gas-phase C2H4 compared to that for the formation of β-C2H4 radical species. Moreover, hydrogenation of C2H5 species, if formed, must overcome significantly large barriers. Oligomers are the most important byproduct of the reaction and they result from the recombination of chemisorbed C2Hx species. These findings rationalize for the first time the applicability of CeO2 as a catalyst for olefin production and potentially broaden its use for the hydrogenation of polyunsaturated and polyfunctionalized substrates containing triple bonds.

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