Litcius/Paper detail

RETRACTED: Solvent Polarity under Vibrational Strong Coupling

Maciej Piejko, Bianca Patrahau, Kripa Joseph, Cyprien Muller, Éloïse Devaux, Thomas W. Ebbesen, Joseph Moran

2023Journal of the American Chemical Society33 citationsDOI

Abstract

Vibrational strong coupling (VSC) occurs when molecular vibrations hybridize with the modes of an optical cavity, an interaction mediated by vacuum fluctuations. VSC has been shown to influence the rates and selectivity of chemical reactions. However, a clear understanding of the mechanism at play remains elusive. Here, we show that VSC affects the polarity of solvents, which is a parameter well-known to influence reactivity. The strong solvatochromic response of Reichardt’s dye (RD) was used to quantify the polarity of a series of alcohol solvents at visible wavelengths. We observed that, by simultaneously coupling the OH and CH vibrational bands of the alcohols, the absorption maximum of Reichardt’s dye redshifted by up to ∼15.1 nm, corresponding to an energy change of 5.1 kJ·mol –1 . With aliphatic alcohols, the magnitude of the absorption change of RD was observed to be related to the length of the alkyl chain, the molecular surface area, and the polarizability, indicating that dispersion forces are impacted by strong coupling. Therefore, we propose that dispersion interactions, which themselves originate from vacuum fluctuations, are impacted under strong coupling and are therefore critical to understanding how VSC influences chemistry.

Topics & Concepts

ChemistryPolarity (international relations)SolvatochromismRotational–vibrational couplingPhotochemistryAbsorption (acoustics)Coupling (piping)SolventSolvent effectsSolvent polarityMolecular vibrationWavelengthChemical physicsReactivity (psychology)Absorption spectroscopyMolecular physicsComputational chemistryMoleculeOpticsOrganic chemistryBiochemistryMechanical engineeringPhysicsEngineeringPathologyAlternative medicineMedicineCellStrong Light-Matter InteractionsSpectroscopy and Quantum Chemical StudiesQuantum Information and Cryptography