Exploring the mechanisms of exciton diffusion improvement in ternary polymer solar cells: From ultrafast to ultraslow temporal scale

Long-range exciton diffusion on picosecond time scale, which serves to efficient charge separation at the donor/acceptor (D/A) interfaces, has been regarded as a key step for the working mechanisms of organic photovoltaics. Rationally understanding and manipulating this vital process over a wide temporal scale remains some challenges, especially in ternary organic solar cells (OSCs). Herein, we reveal how exciton migration behaviors are reasonably improved and maintained relying on the simultaneously enhanced efficiency and thermal stability in the PM6:IT4F:PC71BM and PM6:BTP-4Cl:PC71BM ternary devices. Two separate factors can be responsible for these benefits: (1) the coexistence of dual Forster-type energy transfer (FRET) can contribute to the directed exciton diffusion and rapidly quench the highly excited states to stabilize the energy donors. (2) The more favorable multi-length scale morphologies optimized by the addition of guest PC71BM yield the plentiful interfacial region to shorten the real distance of diffusion process and boost the stability of microstructure. In particular, the diffusion lengths > 10 nm of IT4F singlet excitons induced by dual FRET effects were obtained by employing the exciton-exciton annihilation strategy. These experimental results open a novel horizon for further strengthening efficiency and stability of ternary OSCs from the perspective of improving exciton diffusion.

Automated summary

In this study, the enhancement of exciton migration behaviors in PM6:IT4F:PC71BM and PM6:BTP-4Cl:PC71BM ternary devices was achieved by simultaneously improving efficiency and thermal stability. The coexistence of dual Forster-type energy transfer and the addition of PC71BM contributed to the directed exciton diffusion and stabilized the energy donors, leading to more favorable multi-length scale morphologies.