Investigation of tunable halogen-free solvent engineering on aggregation and miscibility towards high-performance organic solar cells

Eco-friendly and sustainable organic solar cells (OSCs) have become the inevitable choice for the commercialization, which specifically dictates the use of non-halogenated solvents. Although a series of non-halogenated solvents have been introduced to meet such need, non-halogenated OSCs with high-performance are still rare due to the uncontrollable aggregation and penetration behaviors. To mitigate these drawbacks, tunable nonhalogenated solvent engineering (TSE) strategy is proposed via mixing carbon disulfide (CS2) and o-xylene (oXY) solvents with 0.3:0.7 vol ratio. By the merits of solubility and volatilization gradient of TSE strategy, the aggregation and interdiffusion dynamics of donor (D) and acceptor (A) are finely tailored. More crucially, by applying this TSE approach, the non-geminate recombination loss is drastically eliminated along with charge generation/transport/extraction processes are considerably improved by a series of photoelectric measurements. Consequently, the PM6-BTP-eC9 blend based OSCs yield a maximum performance of 17.6% without any additive and/or post treatments, with an improvement of 23.1% compared to that of neat o-XY based counterparts (14.3%), which is among the highest values in the field of halogen-free-solvent-processed OSCs to our best knowledge. All these pronounced that TSE is a feasible and promising strategy to construct the efficient and ecofriendly OSCs for industrial commercialization.

Automated summary

A new strategy called tunable nonhalogenated solvent engineering (TSE) was proposed in this study, which improved the performance and efficiency of organic solar cells prepared with non-halogenated solvents by mixing carbon disulfide and o-xylene.