Enhancing exciton diffusion by reducing energy disorder in organic solar cells

A highly crystalline, highly emissive, and wide-bandgap polymer AC174 with an extremely small Stokes shift is designed and synthesized in water, and is used to reduce system energetic disorder and increase the exciton diffusion length of the classical PM6:Y6 blend system. AC174 is incompatible with PM6 and Y6, improves molecular packing, and reduces system energetic disorder. The long-range Forster resonance energy transfer between the donor and acceptor is enhanced, and the exciton diffusion constant and exciton lifetime are increased, leading to a longer exciton diffusion length and more efficient exciton dissociation and charge generation. The addition of AC174 simultaneously improves the open-circuit voltage, short-circuit current density (J(SC)) and fill factor of PM6:Y6 devices; especially the highest internal quantum efficiency approaches 100%, and the highest J(SC) is 28.4 mA cm(-2). Ternary devices with 5% AC174 in the donors achieve a power conversion efficiency of 17.2%, higher than those of the parent binary devices based on PM6:Y6 (15.9%) and AC174:Y6 (3.24%).

Automated summary

A new polymer AC174 is designed and synthesized to improve the performance of the PM6:Y6 blend system, leading to increased exciton diffusion length and charge separation efficiency, and ultimately enhancing the conversion efficiency of solar cells.