The full potential energy surface
of the catalytic conversion of
furfural to 2-methylfuran on the Cu(111) surface has been systematically
computed on the basis of density functional theory, including dispersion
and zero-point energy corrections. For furfuryl alcohol formation,
the more favorable step is the first H addition to the carbon atom
of the CO group, forming an alkoxyl intermediate (F-CHO +H
→ F-CH2O); the second H atom addition, leading to
furfuryl alcohol formation (F-CH2O + H → F-CH2OH), is the rate-determining step. For 2-methylfuran formation
from furfuryl alcohol dissociation into surface alkyl (F-CH2) and OH groups, H2O formation is the rate-determining
step (OH + H → H2O). Our results explain perfectly
the experimentally observed selective formation of furfuryl alcohol
and the equilibrium of furfural/furfuryl alcohol conversion under
hydrogen-rich conditions as well as the effect of H2O suppressing
furfural conversion. In addition, it is found that dispersion correction
(PBE-D3) overestimates the adsorption energies of furfural, furfuryl
alcohol, and 2-methylfuran considerably, whereas those of H2 and H2O can be reproduced nearly quantitatively. Our
results provide insights into Cu-catalyzed furfural selective conversion
and broaden our fundamental understanding into deoxygenation reactions
of oxygenates involved in the refining of biomass-derived oils.
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