Predicting fluorescence quantum yields for molecules in solution: A critical assessment of the harmonic approximation and the choice of the lineshape function

Humeniuk, Alexander; Bužančić, Margarita; Hoche, Joscha; Cerezo, Javier; Mitrić, Roland; Santoro, Fabrizio; Bonačić‐Koutecký, Vlasta

doi:10.1063/1.5143212

Cited by 48 publications

(108 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[ 142 ] In any case, it is noted that the application of the underlying harmonic approximation for the S 0 potential at such high energies might induce large errors in the calculated rates. [ 247 ] For molecules with comparable molecular (rigid) skeleton, in particular oligomer series such as oligoacenes n Ac (Scheme 3), such approach predicts an increase of k nr with decreasing energy gap between the i and f states (thus for increasing n ). [ 205 ] This “energy gap law” (EGL) was identified as the main reason for the validity of Kasha's rule (emission from S 1 in fluid solution under steady‐state conditions) due to the usually small energy separation found between higher excited states.…”

Section: Molecular Luminescence—intramolecular Processes and Environmental Controlmentioning

confidence: 99%

Luminescence in Crystalline Organic Materials: From Molecules to Molecular Solids

Gierschner

Shi

Milián‐Medina

et al. 2021

Advanced Optical Materials

174

194

View full text Add to dashboard Cite

Luminescent small, all‐organic molecules are of tremendous interest in materials and life science applications. Nevertheless, targeted design requires a basic understanding of the excited state deactivation pathways of the molecules themselves, and the modulations of the processes that occur in the solid state. This particularly concerns crystalline molecular solids, as here not only solid‐state rigidification contributes to these modulations, but specific intermolecular interactions as well. Starting from the molecular properties, this work carefully disentangles all intramolecular and intermolecular factors to the radiative and nonradiative processes in crystalline all‐organic molecular solids to provide guidelines for targeted molecular materials design.

show abstract

Section: Molecular Luminescence—intramolecular Processes and Environmental Controlmentioning

confidence: 99%

Luminescence in Crystalline Organic Materials: From Molecules to Molecular Solids

Gierschner

Shi

Milián‐Medina

et al. 2021

Advanced Optical Materials

174

194

View full text Add to dashboard Cite

show abstract

“…where IC k is internal conversion (IC) rate constant between electronic states with the same spin multiplicity and ISC k is the intersystem crossing (ISC) rate constant between electronic states with different spin multiplicities [21]. The IC k and ISC k rate constants can be calculated using various softwares at different levels of theory [19,20,[22][23][24][25][26][27]. The most popular method is based on correlation functions for estimating Franck-Condon contributions [22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

First-principles calculations of anharmonic and deuteration effects on the photophysical properties of polyacenes and porphyrinoids

Valiev

Nasibullin

Cherepanov

et al. 2020

Phys. Chem. Chem. Phys.

View full text Add to dashboard Cite

show abstract

“…Humeniuk et al assessed the validity of HA for several coumarin dyes when predicting the fluorescence quantum yields in solution. 32 They found that the accuracy of HA for the radiative decay rate is remarkable, while HA will underestimate the IC rates. Hence, HA will lead to an unreliable prediction of fluorescence quantum yield compared to the experiments.…”

Section: Introductionmentioning

confidence: 99%

Evaluating the anharmonicity contributions to the molecular excited state internal conversion rates with finite temperature TD-DMRG

Wang

Ren

Shuai

2021

The Journal of Chemical Physics

View full text Add to dashboard Cite

In this work, we propose a new method to calculate molecular nonradiative electronic relaxation rates based on the numerically exact time-dependent density matrix renormalization group theory. This method could go beyond the existing frameworks under the harmonic approximation (HA) of the potential energy surface (PES) so that the anharmonic effect could be considered, which is of vital importance when the electronic energy gap is much larger than the vibrational frequency. We calculate the internal conversion (IC) rates in a two-mode model with Morse potential to investigate the validity of HA. We find that HA is unsatisfactory unless only the lowest several vibrational states of the lower electronic state are involved in the transition process when the adiabatic excitation energy is relatively low. As the excitation energy increases, HA first underestimates and then overestimates the IC rates when the excited state PES shifts toward the dissociative side of the ground state PES. On the contrary, HA slightly overestimates the IC rates when the excited state PES shifts toward the repulsive side. In both cases, a higher temperature enlarges the error of HA. As a real example to demonstrate the effectiveness and scalability of the method, we calculate the IC rates of azulene from S1 to S0 on the ab initio anharmonic PES approximated by the one-mode representation. The calculated IC rates of azulene under HA are consistent with the analytically exact results. The rates on the anharmonic PES are 30%–40% higher than the rates under HA.

show abstract

Predicting fluorescence quantum yields for molecules in solution: A critical assessment of the harmonic approximation and the choice of the lineshape function

Cited by 48 publications

References 42 publications

Luminescence in Crystalline Organic Materials: From Molecules to Molecular Solids

Luminescence in Crystalline Organic Materials: From Molecules to Molecular Solids

First-principles calculations of anharmonic and deuteration effects on the photophysical properties of polyacenes and porphyrinoids

Evaluating the anharmonicity contributions to the molecular excited state internal conversion rates with finite temperature TD-DMRG

Contact Info

Product

Resources

About