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Abstract
Multi-exciton generation—the creation of multiple charge carrier pairs from a single photon—has been reported for several materials and may dramatically increase solar cell efficiency. Singlet fission, its molecular analogue, may govern multi-exciton generation in a variety of materials, but a fundamental mechanism for singlet fission has yet to be described. Here, we use sophisticated ab initio calculations to show that singlet fission in pentacene proceeds through rapid internal conversion of the photoexcited state into a dark state of multi-exciton character that efficiently splits into two triplets. We show that singlet fission to produce a pair of triplet excitons must involve an intermediate state that (i) has a multi-exciton character, (ii) is energetically accessible from the optically allowed excited state, and (iii) efficiently dissociates into multiple electron–hole pairs. The rational design of photovoltaic materials that make use of singlet fission will require similar ab initio analysis of multi-exciton states such as the dark state studied here. A fundamental mechanism for singlet fission, a process that may govern instances of multi-exciton generation, has yet to be described. Sophisticated calculations now show that singlet fission in pentacene proceeds through the conversion of a photoexcited state into a dark state of multi-exciton character that subsequently splits into two triplets. Cite this article
Zimmerman, P., Zhang, Z. & Musgrave, C. Singlet fission in pentacene through multi-exciton quantum states. Nature Chem 2, 648–652 (2010). https://doi.org/10.1038/nchem.694 