There is a pressing global need to increase the use of renewable energy sources and limit greenhouse gas emissions. Towards this goal, highly efficient and molecularly selective chemical processes that operate under mild conditions are critical. Plasmonic photocatalysis uses optically-resonant metallic nanoparticles and their resulting plasmonic, electronic, and phononic light-matter interactions to drive chemical reactions. The promise of simultaneous high-efficiency and product-selective reactions with plasmon photocatalysis provides a compelling opportunity to rethink how chemistry is achieved. Plasmonic nanoparticles serve as nanoscale ‘antennas’ that enable strong light–matter interactions, surpassing the light-harvesting capabilities one would expect purely from their size. Complex composite structures, combining engineered light harvesters with more chemically active components, are a focal point of current research endeavors. In this review, we provide an overview of recent advances in plasmonic catalysis. We start with a discussion of the relevant mechanisms in photochemical transformations and explain hot-carrier generation and distributions from several ubiquitous plasmonic antennae. Then we highlight three important types of catalytic processes for sustainable chemistry: ammonia synthesis, hydrogen production and CO2 reduction. To help elucidate the reaction mechanism, both state-of-art electromagnetic calculations and quantum mechanistic calculations are discussed. This review provides insights to better understand the mechanism of plasmonic photocatalysis with a variety of metallic and composite nanostructures toward designing and controlling improved platforms for green chemistry in the future.
Palladium’s
strong reactivity and absorption affinity to
H2 makes it a prime material for hydrogen-based technologies.
Alloying of Pd has been used to tune its mechanical stability, catalytic
activity, and absorption thermodynamics. However, atomistic mechanisms
of hydrogen dissociation and intercalation are informed predominantly
by theoretical calculations, owing to the difficulty in imaging dynamic
metal–gas interactions at the atomic scale. Here, we use in situ environmental high resolution transmission electron
microscopy to directly track the hydrogenation-induced lattice expansion
within AgPd triangular nanoprisms. We investigate the thermodynamics
of the system at the single particle level and show that, contrary
to pure Pd nanoparticles, the AgPd system exhibits α/β
coexistence within single crystalline nanoparticles in equilibrium;
the nanoparticle system also moves to a solid-solution loading mechanism
at lower Ag content than bulk. By tracking the lattice expansion in
real time during a phase transition, we see surface-limited β
phase growth, as well as rapid reorientation of the α/β
interface within individual particles. This secondary rate corresponds
to the speed with which the β phase can restructure and, according
to our atomistic calculations, emerges from lattice strain minimization.
We also observe no preferential nucleation at the sharpest nanoprism
corners, contrary to classical nucleation theory. Our results achieve
atomic lattice plane resolutioncrucial for exploring the role
of crystal defects and single atom sites on catalytic hydrogen splitting
and absorption.
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