Highly efficient exciton transport via transient delocalization in films of poly(3-hexylthiophene) nanofibers prepared by seeded growth

Exciton transport is crucial for light-harvesting devices based on organic semiconductors, such as organic solar cells, photodetectors or photocatalysis systems. Yet, singlet exciton diffusion lengths in conjugated polymer films remain limited to about 10 nm, with associated diffusion constants ($D$) on the order of $10^{-3}-10^{-4}$ cm$^2$/s. Here, we employ the living crystallization-driven self-assembly (CDSA) seeded growth method to prepare highly crystalline nanofibers (NFs) with a core comprised of the visible-light-absorbing semiconducting polymer, regioregular poly(3-hexylthiophene) (rr-P3HT). Films of these NFs show low energetic disorder and an exceptional exciton diffusion constant of $D_{NF}=1.1\pm0.1$ cm$^2$/s, as measured via ultrafast optical microscopy and spectroscopy. Non-adiabatic molecular dynamics simulations suggest that the (interchain) exciton transport is mediated via a `transient delocalization' mechanism made possible via the NFs' extended long-range structural order. Our results suggest that large enhancements to exciton diffusion may be achieved in other organic materials by optimizing structural order to allow transient delocalization. Furthermore, this demonstration of high exciton diffusivity in visible-light-absorbing films opens up possibilities for new device architectures based on materials prepared using the CDSA platform.