1 research outputs found
Differentiating Plasmon-Enhanced Chemical Reactions on AgPd Hollow Nanoplates through Surface-Enhanced Raman Spectroscopy
Plasmonic photocatalysis demonstrates great potential
for efficiently
harnessing light energy. However, the underlying mechanisms remain
enigmatic due to the transient nature of the reaction processes. Typically,
plasmonic photocatalysis relies on the excitation of surface plasmon
resonance (SPR) in plasmonic materials, such as metal nanoparticles,
leading to the generation of high-energy or āhot electronsā,
albeit accompanied by photothermal heating or Joule effect. The ability
of hot electrons to participate in chemical reactions is one of the
key mechanisms, underlying the enhanced photocatalytic activity observed
in plasmonic photocatalysis. Interestingly, surface-enhanced Raman
scattering (SERS) spectroscopy allows the analysis of chemical reactions
driven by hot electrons, as both SERS and hot electrons stem from
the decay of SPR and occur at the hot spots. Herein, we propose a
highly efficient SERS substrate based on cellulose paper loaded with
either Ag nanoplates (Ag NPs) or AgPd hollow nanoplates (AgPd HNPs)
for the in situ monitoring of CāC homocoupling reactions. The
data analysis allowed us to disentangle the impact of hot electrons
and the Joule effect on plasmon-enhanced photocatalysis. Computational
simulations revealed an increase in the rate of excitation of hot
carriers from single/isolated AgPd HNPs to an in-plane with a vertical
stacking assembly, suggesting its promise as a photocatalyst under
broadband light. In addition, the results suggest that the incorporation
of Pd into an alloy with plasmonic properties may enhance its catalytic
performance under light irradiation due to the collection of plasmon-excitation-induced
hot electrons. This work has demonstrated the performance-oriented
synthesis of hybrid nanostructures, providing a unique route to uncover
the mechanism of plasmon-enhanced photocatalysis