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Controlling Molecular Photoisomerization in Photonic Cavities through Polariton Funneling

Inki Lee, Sarah R. Melton, Ding Xu, Milan Delor

2024Journal of the American Chemical Society37 citationsDOI

Abstract

Strong coupling between photonic modes and molecular electronic excitations, creating hybrid light-matter states called polaritons, is an attractive avenue for controlling chemical reactions. Nevertheless, experimental demonstrations of polariton-modified chemical reactions remain sparse. Here, we demonstrate modified photoisomerization kinetics of merocyanine and diarylethene by coupling the reactant's optical transition with photonic microcavity modes. We leverage broadband Fourier-plane optical microscopy to noninvasively and rapidly monitor photoisomerization within microcavities, enabling systematic investigation of chemical kinetics for different cavity-exciton detunings and photoexcitation conditions. We demonstrate three distinct effects of cavity coupling: first, a renormalization of the photonic density of states, akin to a Purcell effect, leads to enhanced absorption and isomerization rates at certain wavelengths, notably red-shifting the onset of photoisomerization. This effect is present under both strong and weak light-matter couplings. Second, kinetic competition between polariton localization into reactive molecular states and cavity losses leads to a suppression of the photoisomerization yield. Finally, our key result is that in reaction mixtures with multiple reactant isomers, exhibiting partially overlapping optical transitions and distinct isomerization pathways, the cavity resonance can be tuned to funnel photoexcitations into specific reactant isomers. Thus, upon decoherence, polaritons localize into a chosen isomer, selectively triggering the latter's photoisomerization despite initially being delocalized across all isomers. This result suggests that careful tuning of the cavity resonance is a promising avenue to steer chemical reactions and enhance product selectivity in reaction mixtures.

Topics & Concepts

PhotoisomerizationChemistryPhotochemistryIsomerizationPhotochromismChemical physicsPolaritonPhotoexcitationAzobenzenePhotonicsResonance (particle physics)OptoelectronicsExcited stateAtomic physicsMaterials scienceMoleculePhysicsBiochemistryCatalysisOrganic chemistryStrong Light-Matter InteractionsThermal Radiation and Cooling TechnologiesPlasmonic and Surface Plasmon Research
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