A molecular interaction-diffusion framework for predicting organic solar cell stability

Rapid increase in the power conversion efficiency of organic solar cells (OSCs) has been achieved with the development of non-fullerene small-molecule acceptors (NF-SMAs). Although the morphological stability of these NF-SMA devices critically affects their intrinsic lifetime, their fundamental intermolecular interactions and how they govern property-function relations and morphological stability of OSCs remain elusive. Here, we discover that the diffusion of an NF-SMA into the donor polymer exhibits Arrhenius behaviour and that the activation energy E-a scales linearly with the enthalpic interaction parameters chi(H) between the polymer and the NF-SMA. Consequently, the thermodynamically most unstable, hypo-miscible systems (high chi) are the most kinetically stabilized. We relate the differences in E-a to measured and selectively simulated molecular self-interaction properties of the constituent materials and develop quantitative property-function relations that link thermal and mechanical characteristics of the NF-SMA and polymer to predict relative diffusion properties and thus morphological stability.

Automated summary

The diffusion of NF-SMA into the donor polymer exhibits Arrhenius behavior, with the activation energy linearly scaling with the enthalpic interaction parameters between the two materials. The most thermodynamically unstable systems are the most kinetically stabilized.