To date, copper is the only monometallic catalyst that can electrochemically reduce CO2 into high value and energy‐dense products, such as hydrocarbons and alcohols. In recent years, great efforts have been directed towards understanding how its nanoscale structure affects activity and selectivity for the electrochemical CO2 reduction reaction (CO2RR). Furthermore, many attempts have been made to improve these two properties. Nevertheless, to advance towards applied systems, the stability of the catalysts during electrolysis is of great significance. This aspect, however, remains less investigated and discussed across the CO2RR literature. In this Minireview, the recent progress on understanding the stability of copper‐based catalysts is summarized, along with the very few proposed degradation mechanisms. Finally, our perspective on the topic is given.
To date, copper is the only monometallic catalyst that can electrochemically reduce CO2 into high value and energy‐dense products, such as hydrocarbons and alcohols. In recent years, great efforts have been directed towards understanding how its nanoscale structure affects activity and selectivity for the electrochemical CO2 reduction reaction (CO2RR). Furthermore, many attempts have been made to improve these two properties. Nevertheless, to advance towards applied systems, the stability of the catalysts during electrolysis is of great significance. This aspect, however, remains less investigated and discussed across the CO2RR literature. In this Minireview, the recent progress on understanding the stability of copper‐based catalysts is summarized, along with the very few proposed degradation mechanisms. Finally, our perspective on the topic is given.
Electrochemical stability of a commercial Au/C catalyst in an acidic electrolyte has been investigated by an accelerated stress test (AST), which consisted of 10,000 voltammetric scans (1 V/s) in the potential range between 0.58 and 1.41 V RHE . Loss of Au electrochemical surface area (ESA) during the AST pointed out to the degradation of Au/C. Coupling of an electrochemical flow cell with ICP-MS showed that only a minor amount of gold is dissolved despite the substantial loss of gold ESA during the AST (∼35% of initial value remains at the end of the AST). According to the electrochemical mass spectrometry experiments, carbon corrosion occurs during the AST but to a minor extent. By using identical location scanning electron microscopy and identical location transmission electron microscopy, it was possible to discern that the dissolution of small Au particles (<5 nm) within the polydisperse Au/C sample is the main degradation mechanism. The mass of such particles gives only a minor contribution to the overall Au mass of the polydisperse sample while giving a major contribution to the overall ESA, which explains a significant loss of ESA and minor loss of mass during the AST. The addition of low amounts of chloride anions (10 −4 M) substantially promoted the degradation of gold nanoparticles. At an even higher concentration of chlorides (10 −2 M), the dissolution of gold was rather effective, which is useful from the recycling point of view when rapid leaching of gold is desirable.
Water electrolysis powered by renewables is regarded
as the feasible
route for the production of hydrogen, obtained at the cathode side
through electrochemical hydrogen evolution reaction (HER). Herein,
we present a rational strategy to improve the overall HER catalytic
performance of Pt, which is known as the best monometallic catalyst
for this reaction, by supporting it on a conductive titanium oxynitride
(TiON
x
) dispersed over reduced graphene
oxide nanoribbons. Characterization of the Pt/TiON
x
composite revealed the presence of small Pt particles with
diameters between 2 and 3 nm, which are well dispersed over the TiON
x
support. The Pt/TiON
x
nanocomposite exhibited improved HER activity and stability with
respect to the Pt/C benchmark in an acid electrolyte, which was ascribed
to the strong metal–support interaction (SMSI) triggered between
the TiON
x
support and grafted Pt nanoparticles.
SMSI between TiON
x
and Pt was evidenced
by X-ray photoelectron spectroscopy (XPS) through a shift of the binding
energies of the characteristic Pt 4f photoelectron lines with respect
to Pt/C. Density functional theory (DFT) calculations confirmed the
strong interaction between Pt nanoparticles and the TiON
x
support. This strong interaction improves the stability
of Pt nanoparticles and weakens the binding of chemisorbed H atoms
thereon. Both of these effects may result in enhanced HER activity.
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