Modeling solvation effects on absorption and fluorescence spectra of indole in aqueous solution

Abou-Hatab, Salsabil; Carnevale, Vincenzo; Matsika, Spiridoula

doi:10.1063/5.0038342

Cited by 10 publications

(13 citation statements)

References 102 publications

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“…While significantly more expensive, we can exactly treat for both mutual polarisation of the solute-solvent mixture, in addition to direct charge interactions. [11][12][13] Common quantum chemical practice dictates that the computation of excitation energies is governed by one of two methods: a state specific method or a linear response method. The former solves the nonlinear Schro ¨dinger equation for only the requested state, and calculates transition energies as differences of the total solute-solvent free energy.…”

Section: Introductionmentioning

confidence: 99%

The quantum chemical solvation of indole: accounting for strong solute–solvent interactions using implicit/explicit models

Manian

Shaw

Lyskov

et al. 2022

Phys. Chem. Chem. Phys.

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Section: Introductionmentioning

confidence: 99%

The quantum chemical solvation of indole: accounting for strong solute–solvent interactions using implicit/explicit models

Manian

Shaw

Lyskov

et al. 2022

Phys. Chem. Chem. Phys.

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“…For that reason, the FC approach cannot be used to model the spectrum of bound-to-continuum transitions. Ensemble methods are also likely more appropriate in systems where electronic states rather than vibrational levels are responsible for the spectral shapes [97].…”

Section: Discussionmentioning

confidence: 99%

Modeling the Electronic Absorption Spectra of the Indocarbocyanine Cy3

2022

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Accurate modeling of optical spectra requires careful treatment of the molecular structures and vibronic, environmental, and thermal contributions. The accuracy of the computational methods used to simulate absorption spectra is limited by their ability to account for all the factors that affect the spectral shapes and energetics. The ensemble-based approaches are widely used to model the absorption spectra of molecules in the condensed-phase, and their performance is system dependent. The Franck–Condon approach is suitable for simulating high resolution spectra of rigid systems, and its accuracy is limited mainly by the harmonic approximation. In this work, the absorption spectrum of the widely used cyanine Cy3 is simulated using the ensemble approach via classical and quantum sampling, as well as, the Franck–Condon approach. The factors limiting the ensemble approaches, including the sampling and force field effects, are tested, while the vertical and adiabatic harmonic approximations of the Franck–Condon approach are also systematically examined. Our results show that all the vertical methods, including the ensemble approach, are not suitable to model the absorption spectrum of Cy3, and recommend the adiabatic methods as suitable approaches for the modeling of spectra with strong vibronic contributions. We find that the thermal effects, the low frequency modes, and the simultaneous vibrational excitations have prominent contributions to the Cy3 spectrum. The inclusion of the solvent stabilizes the energetics significantly, while its negligible effect on the spectral shapes aligns well with the experimental observations.

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“…The Journal of Physical Chemistry A which were published in previous work. 37 In one MD simulation all bonds of the indole solute and water molecules were constrained (C) and in the other they were unconstrained (UC), free to vibrate. In those MD simulations a nonpolarizable force field was used.…”

Section: ■ Methodsmentioning

confidence: 99%

“…Ten configurations of indole·4H 2 O were extracted from two molecular dynamics (MD) simulations, which were published in previous work . In one MD simulation all bonds of the indole solute and water molecules were constrained (C) and in the other they were unconstrained (UC), free to vibrate.…”

Section: Methodsmentioning

confidence: 99%

Effective Fragment Potentials for Microsolvated Excited and Anionic States

et al. 2022

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The effective fragment potential (EFP) approach is a sophisticated hybrid approach that allows the inclusion of solvation effects when describing properties and reactivity in the condensed phase, without using empirical parameters. This work examines the performance of the EFP method when describing microsolvation in electronically excited states of neutrals and anions. The examples selected include both localized valence states, as well as diffuse nonvalence states, which represent greater challenges to conventional electronic structure methods. The equation-of-motion coupled cluster with singles and doubles (EOM-XX-CCSD) methodology has been used to provide the quantum chemical description of both the full microsolvated clusters, and the chromophoric moiety in mixed quantum/EFP calculations. We find that, when averaging over multiple configurations of microsolvated clusters, the differences between QM/EFP and full quantum results are minimal, although individual configurations often have larger errors. As expected, diffuse states have somewhat larger errors, although not significantly so. The close proximity of states leading to mixing can make QM/EFP less accurate because a change of ordering of states can occur. Other properties, such as photoelectron images and lifetimes of metastable states, are very well described for the monohydrated clusters investigated.

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Modeling solvation effects on absorption and fluorescence spectra of indole in aqueous solution

Cited by 10 publications

References 102 publications

The quantum chemical solvation of indole: accounting for strong solute–solvent interactions using implicit/explicit models

The quantum chemical solvation of indole: accounting for strong solute–solvent interactions using implicit/explicit models

Modeling the Electronic Absorption Spectra of the Indocarbocyanine Cy3

Effective Fragment Potentials for Microsolvated Excited and Anionic States

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