Characterizing the Role of Peierls Vibrations in Singlet Fission with the Adaptive Hierarchy of Pure States

Singlet fission, a phenomenon in which a singlet exciton is converted to two triplet excitons, is sensitive to vibrations that perturb couplings between electronic states (i.e., Peierls vibrations). In singlet fission models larger than dimers, the inconvenient scaling of exact simulations has limited treatment of Peierls vibrations to approximate methods. In this letter, we generalize the formally-exact, reduced-scaling adaptive Hierarchy of Pure States (adHOPS) method to account for both Holstein and Peierls vibrations and study singlet fission in ethylphenyl perylene di-imide (EP-PDI). We find that singlet fission is accelerated by constructive interference between charge-transfer mediated pathways when Peierls vibrations break the anti-symmetry of electronic couplings in conjunction with rapid vibrationally-mediated relaxation of singlet excitons. Finally, we extend this singlet fission model to a linear chain of EP-PDI, exploring edge effects and demonstrating the possibility of size-invariant scaling in simulations of singlet fission on 10s-to-100s-of-nm scales.