Realizing record efficiencies for ultra-thin organic photovoltaics through step-by-step optimizations of silver nanowire transparent electrodes

FlexMat Pub Date : 2024-08-18 DOI:10.1002/flm2.30
Xiangjun Zheng, Yiming Wang, Tianyi Chen, Yibo Kong, Xiaoling Wu, Cun Zhou, Qun Luo, Chang-Qi Ma, Lijian Zuo, Minmin Shi, Hongzheng Chen
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Abstract

Ultra-thin (also known as ultra-flexible) organic photovoltaics (OPVs) represent a strong contender among emerging photovoltaic technologies. However, due to the imbalance between the optical and electrical properties of indium tin oxide (ITO)-free transparent electrodes, the ultra-thin OPVs often exhibit lower efficiency compared to the brittle yet more balanced rigid ITO counterparts. Here, we design and fabricate an advanced ultra-thin OPV, which involves a thoroughly optimized silver nanowires (AgNWs) transparent electrode (named AZAT) with excellent optical, electrical and mechanical properties. Specifically, the high-kinetic energy spray-coating method successfully yields a curve-shaped, tightly connected and uniformly distributed AgNWs film, complemented by a capping layer of zinc oxide:aluminum-doped zinc oxide (ZnO:AZO) to improve charge collection capability. Simultaneously, the transparency of the electrode is enhanced through precise optical optimization. Thus, we implant the AZAT-based devices on 1.3 μm polyimide substrates and demonstrate ultra-thin OPVs with a record efficiency of 18.46% and a power density of 40.31 W g−1, which is the highest value for PV technologies. Encouragingly, the AZAT electrode also enables the 10.0 cm2 device to exhibit a high efficiency of 15.67%. These results provide valuable insights for the development of ultra-thin OPVs with high efficiency, low cost, superior flexibility, and up-scaling capacity.

Abstract Image

通过逐步优化银纳米线透明电极,实现创纪录的超薄有机光伏效率
超薄(又称超柔性)有机光伏(OPV)是新兴光伏技术的有力竞争者。然而,由于无铟锡氧化物(ITO)透明电极的光学和电学特性不平衡,超薄 OPV 的效率往往低于脆性但更平衡的刚性 ITO 同类产品。在这里,我们设计并制造了一种先进的超薄 OPV,它采用了经过全面优化的银纳米线(AgNWs)透明电极(命名为 AZAT),具有优异的光学、电学和机械性能。具体来说,高动能喷涂方法成功地生成了一层曲线形、紧密连接且分布均匀的银纳米线薄膜,并辅以氧化锌:掺铝氧化锌(ZnO:AZO)封端层,以提高电荷收集能力。同时,通过精确的光学优化提高了电极的透明度。因此,我们在 1.3 μm 聚酰亚胺衬底上植入了基于 AZAT 的器件,并展示了超薄 OPV,其效率达到创纪录的 18.46%,功率密度达到 40.31 W g-1,这是光伏技术的最高值。令人鼓舞的是,AZAT 电极还使 10.0 平方厘米的设备实现了 15.67% 的高效率。这些结果为开发具有高效率、低成本、优越灵活性和升级能力的超薄 OPV 提供了宝贵的启示。
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