Low-temperature heterogeneous catalytic reaction in an electric field is anticipated as a novel approach for on-demand and small-scale catalytic processes.
Efficient ammonia synthesis at low temperatures is anticipated for establishing a hydrogen carrier system. We reported earlier that application of an electric field on the Cs/Ru/SrZrO3 catalyst enhanced catalytic ammonia synthesis activity. It is now clear that N2 dissociation is activated by hopping protons in the electric field. Efficient ammonia synthesis proceeds by an “associative mechanism” in which N2 dissociates via an N2H intermediate, even at low temperatures. The governing factor of ammonia synthesis activity in an electric field for active metals differed from that in the conventional mechanism. Also, N2H formation energy played an important role. The effects of dopants (Al, Y, Ba, and Ca) on this mechanism were investigated using activity tests and density functional theory calculations to gain insights into the support role in the electric field. Ba and Ca addition showed positive effects on N2H formation energy, leading to high ammonia synthesis activity. The coexistence of proton-donating and electron-donating abilities is necessary for efficient N2H formation at the Ru–support interface.
Fe-supported heterogeneous catalysts
are used for various reactions,
including ammonia synthesis, Fischer–Tropsch synthesis, and
exhaust gas cleaning. For the practical use of Fe-supported catalysts,
suppression of Fe particle agglomeration is the most important issue
to be resolved. As described herein, we found that Al doping in an
oxide support suppresses agglomeration of the supported Fe particle.
Experimental and computational studies revealed two tradeoff Al doping
effects: the Fe particle size decreased and remained without agglomeration
by virtue of the anchoring effect of doped Al. Also, some Fe atoms
anchored by Al cannot function as an active site because of bonding
with oxygen atoms. Using an appropriate amount of Al doping is effective
for increasing the number of active Fe sites and catalytic activity.
This optimized catalyst showed high practical activity and stability
for low-temperature ammonia synthesis in an electric field. The optimized
catalyst of 12.5 wt % Fe/Ce0.4Al0.1Zr0.5O2‑δ showed the highest ammonia synthesis
rate (2.3 mmol g–1 h–1) achieved
to date under mild conditions (464 K, 0.9 MPa) in an electric field
among the Fe catalysts reported.
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