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Controlling Plasmonic Chemistry Pathways through Specific Ion Effects

Andrei Ştefancu, Lin Nan, Li Zhu, Vasile Chiş, Ilko Bald, Min Liu, Nicolae Leopold, Stefan A. Maier, Emiliano Cortés

2022Advanced Optical Materials16 citationsDOIOpen Access PDF

Abstract

Abstract Plasmon‐driven dehalogenation of brominated purines has been recently explored as a model system to understand fundamental aspects of plasmon‐assisted chemical reactions. Here, it is shown that divalent Ca 2+ ions strongly bridge the adsorption of bromoadenine (Br‐Ade) to Ag surfaces. Such ion‐mediated binding increases the molecule's adsorption energy leading to an overlap of the metal energy states and the molecular states, enabling the chemical interface damping (CID) of the plasmon modes of the Ag nanostructures (i.e., direct electron transfer from the metal to Br‐Ade). Consequently, the conversion of Br‐Ade to adenine almost doubles following the addition of Ca 2+ . These experimental results, supported by theoretical calculations of the local density of states of the Ag/Br‐Ade complex, indicate a change of the charge transfer pathway driving the dehalogenation reaction, from Landau damping (in the lack of Ca 2+ ions) to CID (after the addition of Ca 2+ ). The results show that the surface dynamics of chemical species (including water molecules) play an essential role in charge transfer at plasmonic interfaces and cannot be ignored. It is envisioned that these results will help in designing more efficient nanoreactors, harnessing the full potential of plasmon‐assisted chemistry.

Topics & Concepts

PlasmonChemical physicsMoleculeAdsorptionElectron transferMaterials scienceIonNanotechnologyPhotochemistryComputational chemistryChemistryPhysical chemistryOptoelectronicsOrganic chemistryGold and Silver Nanoparticles Synthesis and ApplicationsSpectroscopy and Quantum Chemical StudiesProtein Interaction Studies and Fluorescence Analysis