Electroreduction
of carbon monoxide (CO) possesses great potential
for achieving the renewable synthesis of hydrocarbon chemicals from
CO2. We report here selective reduction of CO to acetate
using Cu–Pd bimetallic electrocatalysts. High activity and
selectivity are demonstrated for CO-to-acetate conversion with >200
mA/cm2 in geometric current density and >65% in Faradaic
efficiency (FE). An asymmetrical C–C coupling mechanism is
proposed to explain the composition-dependent catalytic performance
and high selectivity toward acetate. This mechanism is supported by
the computationally predicted shift of the *CO adsorption from the
top-site configuration on Cu (or Cu-rich) surfaces to the bridge sites
of Cu–Pd bimetallic surfaces, which is also associated with
the reduction of the CO hydrogenation barrier. Further kinetic analysis
of the reaction order with respect to CO and Tafel slope supports
a reaction pathway with *CO–*CHO recombination following a
CO hydrogenation step, which could account for the electroreduction
of CO to acetate on the Cu–Pd bimetallic catalysts. Our work
highlights how heteroatomic alloy surfaces can be tailored to enable
distinct reaction pathways and achieve advanced catalytic performance
beyond monometallic catalysts.
Solid–gas interactions at electrode surfaces determine the efficiency of solid‐oxide fuel cells and electrolyzers. Here, the correlation between surface–gas kinetics and the crystal orientation of perovskite electrodes is studied in the model system La0.8Sr0.2Co0.2Fe0.8O3. The gas‐exchange kinetics are characterized by synthesizing epitaxial half‐cell geometries where three single‐variant surfaces are produced [i.e., La0.8Sr0.2Co0.2Fe0.8O3/La0.9Sr0.1Ga0.95Mg0.05O3−δ/SrRuO3/SrTiO3 (001), (110), and (111)]. Electrochemical impedance spectroscopy and electrical conductivity relaxation measurements reveal a strong surface‐orientation dependency of the gas‐exchange kinetics, wherein (111)‐oriented surfaces exhibit an activity >3‐times higher as compared to (001)‐oriented surfaces. Oxygen partial pressure (pO2)‐dependent electrochemical impedance spectroscopy studies reveal that while the three surfaces have different gas‐exchange kinetics, the reaction mechanisms and rate‐limiting steps are the same (i.e., charge‐transfer to the diatomic oxygen species). First‐principles calculations suggest that the formation energy of vacancies and adsorption at the various surfaces is different and influenced by the surface polarity. Finally, synchrotron‐based, ambient‐pressure X‐ray spectroscopies reveal distinct electronic changes and surface chemistry among the different surface orientations. Taken together, thin‐film epitaxy provides an efficient approach to control and understand the electrode reactivity ultimately demonstrating that the (111)‐surface exhibits a high density of active surface sites which leads to higher activity.
A combined density functional theory and solid-state nudged elastic band study is presented to investigate the martensitic transformation between β → (α″, ω) phases in the Ti-Ta system. The minimum energy paths along the transformation are calculated and the transformation mechanisms as well as relative stabilities of the different phases are discussed for various compositions. The analysis of the transformation paths is complemented by calculations of phonon spectra to determine the dynamical stability of the β, α″, and ω phase. Our theoretical results confirm the experimental findings that with increasing Ta concentration there is a competition between the destabilisation of the α″ and ω phase and the stabilisation of the high-temperature β phase.
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