Plasmonic catalysis takes advantage of the surface plasmon resonance (SPR) excitation to drive or accelerate chemical transformations. In addition to the plasmonic component, the control over metal-support interactions in these catalysts is expected to strongly influence the performances. For example, CeO2 has been widely employed towards oxidation reactions due to its oxygen mobility and storage properties, which allow for the formation of Ce3+ sites and adsorbed oxygen species from metal-support interactions. It is anticipated that these species may be activated by the SPR excitation and contribute to the catalytic activity of the material. Thus, a clear understanding of the role played by the SPR-mediated activation of surface oxide species at the metal-support interface is needed in order to take advantage of this phenomenon. Herein, we describe and quantify the contribution from active surface oxide species at the metal-support interface (relative to O2 from air) to the activities in green SPR-mediated oxidation reactions. We employed CeO2 decorated with Au NPs (Au/CeO2) as a model plasmonic catalyst and the oxidation of p-aminothiophenol (PATP) and aniline as proof-of-concept transformations. We compared the results with SiO2 decorated with Au NPs (Au/SiO2), in which the formation of surface oxide species at the metal-support interface is not expected. We found that the SPR-mediated activation of surface oxide species at the metal-support interface in Au/CeO2 played a pivotal role in the detected activities, being even higher than the contribution coming from the activation of O2 from air.
Photocatalysis provides a sustainable pathway to produce
the consumer
chemical H2O2 from atmospheric O2 via an oxygen reduction reaction (ORR). Such an alternative is attractive
to replace the cumbersome traditional anthraquinone method for H2O2 synthesis on a large scale. Carbon nitrides
have shown very interesting results as heterogeneous photocatalysts
in ORR because their covalent two-dimensional (2D) structure is believed
to increase selectivity toward the two-electron process. However,
an efficient and scalable application of carbon nitrides for this
reaction is far from being achieved. Poly(heptazine imides) (PHIs)
are a more powerful subgroup of carbon nitrides whose structure provides
high crystallinity and a scaffold to host transition-metal single
atoms. Herein, we show that PHIs functionalized with sodium and the
recently reported fully protonated PHI exhibit high activity in two-electron
ORR under visible light. The latter converted O2 to up
to 1556 mmol L–1 h–1 g–1 H2O2 under 410 nm irradiation using inexpensive
but otherwise chemically demanding glycerin as a sacrificial electron
donor. We also prove that functionalization with transition metals
is not beneficial for H2O2 synthesis, as the
metal also catalyzes its decomposition. Transient photoluminescence
spectroscopy suggests that H-PHIs exhibit higher activity due to their
longer excited-state lifetime. Overall, this work highlights the high
photocatalytic activity of the rarely examined fully protonated PHI
and represents a step forward in the application of inexpensive covalent
materials for photocatalytic H2O2 synthesis.
Solar-to-chemical conversion via photocatalysis is of paramount importance for a sustainable future. Thus, investigating the synergistic effects promoted by light in photocatalytic reactions is crucial. The tandem oxidative coupling of alcohols and amines is an attractive route to synthesize imines. Here, we unravel the performance and underlying reaction pathway in the visible-light-driven tandem oxidative coupling of benzyl alcohol and aniline employing Au/CeO2 nanorods as catalysts. We propose an alternative reaction pathway for this transformation that leads to improved efficiencies relative to individual CeO2 nanorods, in which the localized surface plasmon resonance (LSPR) excitation in Au nanoparticles (NPs) plays an important role. Our data suggests a synergism between the hot electrons and holes generated from the LSPR excitation in Au NPs. While the oxygen vacancies in CeO2 nanorods trap the hot electrons and facilitate their transfer to adsorbed O2 at surface vacancy sites, the hot holes in the Au NPs facilitate the α-H abstraction from the adsorbed benzyl alcohol, evolving into benzaldehyde, which then couples with aniline in the next step to yield the corresponding imine. Finally, cerium-coordinated superoxide species abstract hydrogen from the Au surface, regenerating the catalyst surface.
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