posted on 2017-04-05, 08:19authored byRyan Lacdao Arevalo, Susan Meñez Aspera, Mary Clare Sison Escaño, Hiroshi Nakanishi, Hideaki Kasai
Elucidating the reaction
mechanism of steam methane reforming (SMR)
is imperative for the rational design of catalysts for efficient hydrogen
production. In this paper, we provide mechanistic insights into SMR
on Ru surface using first principles calculations based on dispersion-corrected
density functional theory. Methane activation (i.e., C–H bond
cleavage) was found to proceed via a thermodynamically exothermic
dissociative adsorption process, resulting in (CHy + zH)* species (“*” denotes
a surface-bound state, and y + z = 4), with C* and CH* being the most stable adsorbates. The calculation
of activation barriers suggests that the conversion of C* into O-containing
species via C–O bond formation is kinetically slow, indicating
that the surface reaction of carbon intermediates with oxygen is a
possible rate-determining step. The results suggest the importance
of subsequent elementary reactions following methane activation in
determining the formation of stable carbon structures on the surface
that deactivates the catalyst or the conversion of carbon into O-containing
species.