Heterogeneous Singlet Fission in a Covalently Linked Pentacene Dimer (2304.05432v1)

Abstract: Molecular dimers are widely utilized as a tool to investigate the structure-property relationships behind the complex photophysical processes of condensed-phase systems, where structural tuning remains a challenge. This approach often implicitly treats the dimers as static, with their relevant state energies and couplings determined by their optimized geometry. Here, we consider the shortcomings of this approach: dimers are more accurately treated as dynamic model systems, with the potential for significant conformational heterogeneity that evolves in time and is intimately connected with interchromophore coupling strengths. We highlight this concept in the singlet fission dynamics of a pentacene dimer that is covalently linked through phenyl-diketopyrrolopyrrole and acetylene bridges. Unrestricted rotations lead to a vast array of rotational conformers in the ground state. Consequently, we find that every step in the cascade of singlet fission processes - triplet-pair formation from S1, triplet-pair recombination, spin evolution within the pair, and free triplet formation - is qualitatively and quantitatively altered by the conformer geometry. At room temperature, we find evidence of dynamic interconversion between conformers on the multiple TT surfaces. Measurements in frozen solution at 150 K emphasize the significance of static disorder. Our data reveals the presence of sub-populations that result in excitation-dependent electron spin polarization. These phenomena demand consideration of multidimensional potential energy surfaces that define multiple sub-ensembles in the excited state, a picture we refer to as heterogeneous singlet fission. More broadly, our results call into question the general static approach to molecular dimer photophysics, that each step in consecutive excited-state relaxation pathways can be delineated with a single, unique rate constant and yield.