Planar heterojunctions for reduced non-radiative open-circuit voltage loss and enhanced stability of organic solar cells

Compared to bulk heterojunctions (BHJs) in organic solar cells (OSCs), planar heterojunctions (PHJs) avoid complicated morphology control entirely and morphology disorder caused by physical blending, and show huge potentials to realize less traps and better stability for OSCs. In this study, solution-processed fused-ring electron acceptors, replacing traditional fullerene acceptors such as C-60 and C-70, with several vacuum-deposited donors were employed to fabricate PHJ-OSCs. PHJ-OSCs exhibit a much lower trap density of 10(15) cm(-3) magnitude than that of BHJ counterpart devices (10(16) cm(-3) magnitude). Furthermore, PHJ-OSCs achieved the highest electroluminescence efficiency of 5.8 x 10(-3) and the smallest non-radiative open-circuit voltage loss of 0.13 V in the field of OSCs to date. Meanwhile, PHJ-OSCs presented much better stability under illumination than BHJ devices. Moreover, this simple PHJ-OSC fabrication method can be further extended to different acceptor systems to build efficient and stable OSCs.

Automated summary

Planar heterojunctions (PHJs) have shown potential for achieving less traps and better stability compared to bulk heterojunctions (BHJs) in organic solar cells (OSCs). By using solution-processed fused-ring electron acceptors, PHJ-OSCs demonstrated high electroluminescence efficiency and stability, which can be further extended to different acceptor systems for efficient and stable OSCs.