info:eu-repo/semantics/article
Fluorescence Quantum Yields in Complex Environments from QM-MM TDDFT Simulations: The Case of Indole in Different Solvents
Fecha
2020-11Registro en:
Díaz Mirón, Gonzalo; González Lebrero, Mariano Camilo; Fluorescence Quantum Yields in Complex Environments from QM-MM TDDFT Simulations: The Case of Indole in Different Solvents; American Chemical Society; Journal of Physical Chemistry A; 124; 46; 11-2020; 9503-9512
1089-5639
CONICET Digital
CONICET
Autor
Díaz Mirón, Gonzalo
González Lebrero, Mariano Camilo
Resumen
Fluorescence is commonly exploited to probe microscopic properties. An important example is tryptophan in protein environments, where variations in fluorescence quantum yield, and in absorption and emission maxima, are used as indicators of changes in the environment. Modeling the fluorescence quantum yield requires the determination of both radiative and non-radiative decay constants, both on the potential energy surface of the excited fluorophore. Furthermore, the inclusion of complex environments implies their accurate representation as well as extensive configurational sampling. In this work, we present and test various methodologies based on TD-DFT and QM-MM molecular dynamics that take all these requirements into account to provide a quantitative prediction of the effect of the environment on the fluorescence quantum yield of indole, the tryptophan fluorophore. This investigation paves the way for applications to the realistic spectroscopic characterization of the local protein environment of tryptophan from computer simulations.