Dramatic improvement in the stability and mechanism of high-performance inverted polymer solar cells featuring a solution-processed buffer layer.
Yun-Ming SungCheng-Hsun-Tony ChangCheng-Si TsaoHua-Kai LinHou-Chin ChaPei-Cheng JiangTian-Cheng LiuKang-Wei ChangYu-Ching HuangJyh-Shen TsayPublished in: Nanoscale (2023)
In this study, we demonstrate inverted PTB7:PC 71 BM polymer solar cells (PSCs) featuring a solution-processed s-MoO 3 hole transport layer (HTL) that can, after thermal aging at 85 °C, retain their initial power conversion efficiency (PCE) for at least 2200 h. The T 80 lifetimes of the PSCs incorporating the novel s-MoO 3 HTL were up to ten times greater than those currently reported for PTB7- or low-band-gap polymer:PCBM PSCs, the result of the inhibition of burn-in losses and long-term degradation under various heat-equivalent testing conditions. We used X-ray photoelectron spectroscopy (XPS) to study devices containing thermally deposited t-MoO 3 and s-MoO 3 HTLs and obtain a mechanistic understanding of how the robust HTL is formed and how it prevented the PSCs from undergoing thermal degradation. Heat tests revealed that the mechanisms of thermal inter-diffusion and interaction of various elements within active layer/HTL/Ag electrodes controlled by the s-MoO 3 HTL were dramatically different from those controlled by the t-MoO 3 HTL. The new prevention mechanism revealed here can provide the conceptual strategy for designing the buffer layer in the future. The PCEs of PSCs featuring s-MoO 3 HTLs, measured in damp-heat (65 °C/65% RH; 85 °C per air) and light soaking tests, confirmed their excellent stability. Such solution-processed MoO 3 HTLs appear to have great potential as replacements for commonly used t-MoO 3 HTLs.