In the photoluminescence spectra of thin films made of singlet fission (SF) materials emission features that are red-shifted from the free exciton emission are of particular interest. They can be fingerprints of the correlated triplet-pair state and as such offer insights into the mechanisms of the multistep SF process. However, excimer formation or trap-state population can also cause such features and a clear disentanglement of the various contributions can be challenging. Here, we use blends of anthradithiophene (ADT) and weakly interacting organic semiconductors to control the polarizability of the molecular environment and, thus, to distinguish between excimer emission and emission from the correlated triplet-pair state. Using time-resolved photoluminescence spectroscopy measurements, we clarify the relation between excimer formation and SF in ADT and find that excimer formation constitutes a parallel relaxation channel for the exciton and neither mediates nor hinders SF.
The coherent distribution of an electronic excitation over multiple organic molecules in the solid state, namely excited-state delocalization, plays an important role in photophysical processes such as singlet fission. However, experimental studies of the influence of excited-state delocalization on singlet fission have been challenging mainly for two reasons. First, there is no easy way of measuring the excited-state delocalization, and second, tracking the resulting changes for singlet fission is demanding due to the triplet-pair state, which is a crucial intermediate in singlet fission, being an optically dark state and hence hard to access experimentally. Binary systems offer a way to adapt the growth conditions of a singlet fission material, which enables tuning of the excited-state delocalization, possibly due to the impact of structural disorder on exciton localization. By varying the growth conditions, we demonstrate that emission from the triplet-pair state via Herzberg−Teller coupling is detectable in films with low growth rates of the singlet fission material, while the triplet-pair state shows no luminescence in the other cases due to triplet dissociation outcompeting the luminescent decay. With this we find that triplet-pair state luminescence correlates with higher excited-state delocalization.
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