A meta-alkylthio-phenyl chain-substituted small-molecule donor as the third component for high-efficiency organic solar cells

Ternary organic solar cells (OSCs) have attracted increasing attention because they are a feasible and efficient strategy to improve the power conversion efficiency (PCE) of OSCs. However, the rational molecular design of guest materials with a suitable absorption spectrum, energy level and molecular packing is still challenging. Herein, a large-bandgap small-molecule (SM) donor, BTC, incorporated with meta-alkylthio-phenyl-substituted benzo[1,2-b : 4,5-b ']dithiophene (BDT) as the core, was designed and synthesized for high-performance ternary OSCs. It possesses a deeper HOMO (highest occupied molecular orbital) level compared to PM6, which leads to a higher open-circuit voltage (V-OC). Moreover, BTC exhibits good miscibility and complementary absorption with PM6 in the near-ultraviolet region, favoring the photovoltaic performance of OSCs by enhancing the short-circuit current density (J(SC)). Additionally, the ternary blend film with 15 wt% BTC achieved an optimized morphology with a nanofibrous network and strong face-on molecular stack, resulting in higher and more balanced charge mobilities, lower charge recombination and more efficient exciton dissociation compared to the binary blend. Therefore, we have successfully demonstrated a PCE of 17.32% for the ternary OSCs with 15 wt% BTC, with simultaneously improved V-OC, J(SC) and FF compared to the PM6 : Y6 binary OSCs (15.51%). Moreover, the replacement of the acceptor with L8-BO further improves the PCE of ternary OSCs by up to 18.41%. This study provides a promising building block and effective design to fulfill the prerequisites of the absorption spectrum, molecular packing, energetics, and miscibility of small-molecule donors to achieve high-performance ternary OSCs.

Automated summary

A new large-bandgap small-molecule (SM) donor, BTC, was designed and synthesized for high-performance ternary organic solar cells (OSCs), achieving an improved open-circuit voltage (V-OC) and short-circuit current density (J(SC)). The ternary blend film with 15 wt% BTC exhibited an optimized morphology with higher and more balanced charge mobilities.