Litcius/Paper detail

Computational Protocol To Predict Anti-Kasha Emissions: The Case of Azulene Derivatives

Koen Veys, Daniel Escudero

2020The Journal of Physical Chemistry A61 citationsDOIOpen Access PDF

Abstract

In this contribution, we present a computational protocol to predict anti-Kasha photoluminescence. The herein developed protocol is based on state-of-the-art quantum chemical calculations and excited-state decay rate theories (i.e., thermal vibration correlation function formalism), along with appropriate kinetic models which include all relevant electronic states. This protocol is validated for a series of azulene derivatives. For this series, we have computed absorption and emission spectra for both their first and second excited states, their radiative and nonradiative rates, as well as fluorescence yields from the two different excited states. All the studied azulene derivatives are predicted to exclusively display anomalous anti-Kasha S2 emission. A quantitative agreement for the herein computed excited-state spectra, lifetimes, and fluorescence quantum yields is obtained with respect to the experimental values. Given the increasing interest in anti-Kasha emitters, we foresee that the herein developed computational protocol can be used to prescreen dyes with the desired aforementioned anomalous photoluminescence properties.

Topics & Concepts

AzuleneExcited stateRadiative transferPhotoluminescenceChemistryFluorescenceChemical physicsMolecular physicsComputational chemistryAtomic physicsPhysicsPhotochemistryQuantum mechanicsOptoelectronicsPhotochemistry and Electron Transfer StudiesSynthesis and Properties of Aromatic CompoundsLuminescence and Fluorescent Materials