Recently, there have
been renewed interests in exploring new catalysts
for ammonia synthesis under mild conditions. Electride-based catalysts
are among the emerging ones. Ruthenium particles supported on an electride
composed of a mixture of calcium and aluminum oxides (C12A7) have
attracted great attention for ammonia synthesis due to their facile
ability in activating N2 under ambient pressure. However,
the exact nature of the reactive hydrogen species and the role of
electride support still remain elusive for this catalytic system.
In this work, we report for the first time that the surface-adsorbed
hydrogen, rather than the hydride encaged in the C12A7 electride,
plays a major role in ammonia synthesis over the Ru/C12A7 electride
catalyst with the aid of in situ neutron scattering
techniques. Combining in situ neutron diffraction,
inelastic neutron spectroscopy, density functional theory (DFT) calculation,
and temperature-programmed reactions, the results provide direct evidence
for not only the presence of encaged hydrides during ammonia synthesis
but also the strong thermal and chemical stability of the hydride
species in the Ru/C12A7 electride. Steady state isotopic transient
kinetic analysis (SSITKA) of ammonia synthesis showed that the coverage
of reactive intermediates increased significantly when the Ru particles
were promoted by the electride form (coverage up to 84%) of the C12A7
support rather than the oxide form (coverage up to 15%). Such a drastic
change in the intermediate coverage on the Ru surface is attributed
to the positive role of electride support where the H2 poisoning
effect is absent during ammonia synthesis over Ru. The finding of
this work has significant implications for understanding catalysis
by electride-based materials for ammonia synthesis and hydrogenation
reactions in general.
MXenes, a new family of two-dimensional (2D) transition-metal carbides, nitrides, and carbonitrides, have received considerable attention in the energy and environmental applications due to their intriguing electronic, electrochemical, optical, and...
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