An attractive field of plasmon-mediated
chemical reactions (PMCRs)
is developing rapidly, but there is still incomplete understanding
of how to control the kinetics of such a reaction related to hot carriers.
Here, we chose 8-bromoadenine (8BrAd) as a probe molecule of hot electrons
to investigate the influence of the electrode potential, laser wavelength,
and power on the PMCR kinetics on silver nanoparticle-modified silver
electrodes. Plasmonic hot electron-mediated cleavage of the C–Br
bond in 8BrAd has been investigated by combining in situ electrochemical
surface-enhanced Raman spectroscopy and density functional theory
calculations. The experimental and theoretical results reveal that
the energy position of plasmon relaxation-generated hot electrons
can be modulated conveniently by applied potentials and laser light.
This allows the proposal of a mechanism of modulating the matching
energy of the hot electron of plasmon relaxation to promote the efficiency
of PMCRs in electrochemical interfaces. Our work will be helpful to
design surface plasmon resonance photoelectrochemical reactions on
metal electrode surfaces of nanostructures with higher efficiency.
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