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Hauptverfasser: Vergauwe, Robrecht M. A., Toppari, J. Jussi, Groenhof, Gerrit
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2605.06002
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author Vergauwe, Robrecht M. A.
Toppari, J. Jussi
Groenhof, Gerrit
author_facet Vergauwe, Robrecht M. A.
Toppari, J. Jussi
Groenhof, Gerrit
contents Recent reports suggest that chemical reaction rates can change when reactants are placed inside an optical cavity. These effects have been attributed to the hybridization of molecular vibrational modes with cavity modes into polaritons, but the underlying mechanism remains debated. Recently, attempts to reproduce the key experiments have sometimes failed, which poses also ambiguity and impedes the determination of the possible mechanism. Without a reliable theoretical framework, polaritonic chemistry -- which seeks to use optical resonators as catalysts to control reactions -- has reached a pivotal stage. Standardized protocols for reproducible cavity experiments are therefore urgently needed. Here, we identify pitfalls in approaches that monitor reaction progress with UV/Vis spectroscopy. Using the Transfer Matrix Method, we analyze a model pseudo-first-order reaction and assess how transient cavity thickness variations, cavity inhomogeneity, and fitting protocols influence the extracted rate constant. We find that changes in cavity thickness upon reactant introduction can strongly distort apparent kinetics when monitoring at a single wavelength, an artifact that can be mitigated by spectral smoothing. Additionally, we demonstrate that, unlike in many previous studies, the asymptotic extinction should be treated as a fitting parameter rather than fixed to the final experimental value. By identifying these pitfalls, our work lays the foundation for more robust analyses and reliable measurements in polaritonic chemistry.
format Preprint
id arxiv_https___arxiv_org_abs_2605_06002
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Toward Reliable Spectroscopic Analysis of Reaction Kinetics in Polaritonic Chemistry
Vergauwe, Robrecht M. A.
Toppari, J. Jussi
Groenhof, Gerrit
Chemical Physics
Recent reports suggest that chemical reaction rates can change when reactants are placed inside an optical cavity. These effects have been attributed to the hybridization of molecular vibrational modes with cavity modes into polaritons, but the underlying mechanism remains debated. Recently, attempts to reproduce the key experiments have sometimes failed, which poses also ambiguity and impedes the determination of the possible mechanism. Without a reliable theoretical framework, polaritonic chemistry -- which seeks to use optical resonators as catalysts to control reactions -- has reached a pivotal stage. Standardized protocols for reproducible cavity experiments are therefore urgently needed. Here, we identify pitfalls in approaches that monitor reaction progress with UV/Vis spectroscopy. Using the Transfer Matrix Method, we analyze a model pseudo-first-order reaction and assess how transient cavity thickness variations, cavity inhomogeneity, and fitting protocols influence the extracted rate constant. We find that changes in cavity thickness upon reactant introduction can strongly distort apparent kinetics when monitoring at a single wavelength, an artifact that can be mitigated by spectral smoothing. Additionally, we demonstrate that, unlike in many previous studies, the asymptotic extinction should be treated as a fitting parameter rather than fixed to the final experimental value. By identifying these pitfalls, our work lays the foundation for more robust analyses and reliable measurements in polaritonic chemistry.
title Toward Reliable Spectroscopic Analysis of Reaction Kinetics in Polaritonic Chemistry
topic Chemical Physics
url https://arxiv.org/abs/2605.06002