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Plasmonic pathway to hybrid nanomaterials through energy transfer

Hyun Jung Oh, Subhojyoti Chatterjee, Zhenyang Jia, Eric Gomez, Stephen Lee, Jiamu Lin, Ojasvi Verma, Stephan Link, Christy F. Landes

2025Science Advances9 citationsDOIOpen Access PDF

Abstract

Plasmon-induced resonance energy transfer (PIRET) is a promising approach for plasmonic photocatalysis and energy conversion, but challenges include elucidating the mechanism and maximizing its efficiency, both of which are hampered by competing processes. Another challenge is demonstrating that PIRET can photoinitiate reactions that follow efficient pathways compared to bulk processes. We report a plasmon-induced route to plasmonic-polymer hybrid nanomaterials using in operando single-particle spectroelectrochemistry. An energy transfer efficiency of 40% is achievable when the spectral overlap between gold nanorod scattering and polymer absorption is maximized. We also show that PIRET-initiated polymerization proceeds through a different mechanism than bulk polymerization, supported by spectroscopic evidence and density functional theory calculations, highlighting efficient energy cascading from photon to plasmon to exciton and, lastly, to unconventional light-initiated chemistry.

Topics & Concepts

PlasmonNanomaterialsMaterials scienceNanorodNanotechnologyEnergy transferExcitonPolymerizationScatteringSurface plasmon resonanceAbsorption (acoustics)Density functional theoryMechanism (biology)OptoelectronicsPhotonPolymerFörster resonance energy transferLight scatteringPhotocatalysisEnergy (signal processing)Energy transformationResonance (particle physics)Resonant inductive couplingLight energyGold and Silver Nanoparticles Synthesis and ApplicationsQuantum Dots Synthesis And PropertiesPlasmonic and Surface Plasmon Research
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