The
influence of electrode surface structure on electrochemical
reaction rates and mechanisms is a major theme in electrochemical
research, especially as electrodes with inherent structural heterogeneities
are used ubiquitously. Yet, probing local electrochemistry and surface
structure at complex surfaces is challenging. In this paper, high
spatial resolution scanning electrochemical cell microscopy (SECCM)
complemented with electron backscatter diffraction (EBSD) is demonstrated
as a means of performing ‘pseudo-single-crystal’ electrochemical
measurements at individual grains of a polycrystalline platinum electrode,
while also allowing grain boundaries to be probed. Using the Fe2+/3+ couple as an illustrative case, a strong correlation
is found between local surface structure and electrochemical activity.
Variations in electrochemical activity for individual high index grains,
visualized in a weakly adsorbing perchlorate medium, show that there
is higher activity on grains with a significant (101) orientation
contribution, compared to those with (001) and (111) contribution,
consistent with findings on single-crystal electrodes. Interestingly,
for Fe2+ oxidation in a sulfate medium a different pattern
of activity emerges. Here, SECCM reveals only minor variations in
activity between individual grains, again consistent with single-crystal
studies, with a greatly enhanced activity at grain boundaries. This
suggests that these sites may contribute significantly to the overall
electrochemical behavior measured on the macroscale.
A surface structural preference for (1 0 0) terraces of fcc metals is displayed by many bond-breaking or bond-making reactions in electrocatalysis. Here, this phenomenon is explored in the electrochemical oxidation of dimethyl ether (DME) on platinum. The elementary C-O bond-breaking step is identified and clarified by combining information obtained from single-crystal experiments and density functional theory (DFT) calculations. Experiments on Pt(1 0 0), Pt(5 1 0), and Pt(10 1 0) surfaces show that the surface structure sensitivity is due to the bond-breaking step, which is unfavorable on step sites. DFT calculations suggest that the precursor for the bond-breaking step is a CHOC adsorbate that preferentially adsorbs on a square ensemble of four neighboring atoms on Pt(1 0 0) terraces, named as "the active site". Step sites fail to strongly adsorb CHOC and are, therefore, ineffective in breaking C-O bonds, resulting in a decrease in activity on surfaces with increasing step density. Our combined experimental and computational results allow the formulation of a new mechanism for the electro-oxidation of DME as well as a simple general formula for the activity of different surfaces toward electrocatalytic reactions that prefer (1 0 0) terrace active sites.
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