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Energy-efficient pathway for selectively exciting solute molecules to high vibrational states via solvent vibration-polariton pumping

Tao E. Li, Abraham Nitzan, Joseph E. Subotnik

2022Nature Communications38 citationsDOIOpen Access PDF

Abstract

Abstract Selectively exciting target molecules to high vibrational states is inefficient in the liquid phase, which restricts the use of IR pumping to catalyze ground-state chemical reactions. Here, we demonstrate that this inefficiency can sometimes be solved by confining the liquid to an optical cavity under vibrational strong coupling conditions. For a liquid solution of 13 CO 2 solute in a 12 CO 2 solvent, cavity molecular dynamics simulations show that exciting a polariton (hybrid light-matter state) of the solvent with an intense laser pulse, under suitable resonant conditions, may lead to a very strong (>3 quanta) and ultrafast (<1 ps) excitation of the solute, even though the solvent ends up being barely excited. By contrast, outside a cavity the same input pulse fluence can excite the solute by only half a vibrational quantum and the selectivity of excitation is low. Our finding is robust under different cavity volumes, which may lead to observable cavity enhancement on IR photochemical reactions in Fabry–Pérot cavities.

Topics & Concepts

VibrationMoleculeSolventChemical physicsPolaritonVibrational energyMaterials scienceMolecular physicsAtomic physicsComputational chemistryChemistryOptoelectronicsPhysicsAcousticsOrganic chemistryStrong Light-Matter InteractionsThermal Radiation and Cooling TechnologiesQuantum and electron transport phenomena
Energy-efficient pathway for selectively exciting solute molecules to high vibrational states via solvent vibration-polariton pumping | Litcius