Acrolein
hydrogenation via allyl alcohol, propanal, and enol into
propanol on the Ni(111) surface has been investigated using the spin-polarized
periodic density functional theory method. On the basis of the computed
adsorption energies and effective hydrogenation barriers, acrolein
hydrogenation into propanal and allyl alcohol obeys the Langmuir–Hinshelwood
mechanism and propanal formation is more favored kinetically and thermodynamically
than allyl alcohol formation. Hydrogenation of propanal and allyl
alcohol should follow the Eley–Rideal mechanism. The adsorption
energies of acrolein, allyl alcohol, and propanal along with the partial
hydrogenation selectivity on Ni, Au, Ag, and Pt catalysts have been
compared and discussed