The carbon–carbon coupling via electrochemical reduction of carbon dioxide represents the biggest challenge for using this route as platform for chemicals synthesis. Here we show that nanostructured iron (III) oxyhydroxide on nitrogen-doped carbon enables high Faraday efficiency (97.4%) and selectivity to acetic acid (61%) at very-low potential (−0.5 V vs silver/silver chloride). Using a combination of electron microscopy, operando X-ray spectroscopy techniques and density functional theory simulations, we correlate the activity to acetic acid at this potential to the formation of nitrogen-coordinated iron (II) sites as single atoms or polyatomic species at the interface between iron oxyhydroxide and the nitrogen-doped carbon. The evolution of hydrogen is correlated to the formation of metallic iron and observed as dominant reaction path over iron oxyhydroxide on oxygen-doped carbon in the overall range of negative potential investigated, whereas over iron oxyhydroxide on nitrogen-doped carbon it becomes important only at more negative potentials.
We have studied enantiospecific differences in the adsorption of (S)- and (R)-alanine on Cu{531}
R
using
low-energy electron diffraction (LEED), X-ray photoelectron spectroscopy, and near edge X-ray absorption
fine structure (NEXAFS) spectroscopy. At saturation coverage, alanine adsorbs as alaninate forming a
p(1 × 4) superstructure. LEED shows a significantly higher degree of long-range order for the S than for the
R enantiomer. Also carbon K-edge NEXAFS spectra show differences between (S)- and (R)-alanine in the
variations of the π resonance when the linear polarization vector is rotated within the surface plane. This
indicates differences in the local adsorption geometries of the molecules, most likely caused by the interaction
between the methyl group and the metal surface and/or intermolecular hydrogen bonds. Comparison with
model calculations and additional information from LEED and photoelectron spectroscopy suggest that both
enantiomers of alaninate adsorb in two different orientations associated with triangular adsorption sites on
{110} and {311} microfacets of the Cu{531} surface. The experimental data are ambiguous as to the exact
difference between the local geometries of the two enantiomers. In one of two models that fit the data equally
well, significantly more (R)-alaninate molecules are adsorbed on {110} sites than on {311} sites whereas for
(S)-alaninate the numbers are equal. The enantiospecific differences found in these experiments are much
more pronounced than those reported from other ultrahigh vacuum techniques applied to similar systems.
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