材料科学
钝化
钙钛矿(结构)
水分
光伏
光伏系统
卤化物
制作
纳米技术
光电子学
化学工程
图层(电子)
复合材料
无机化学
电气工程
病理
化学
工程类
替代医学
医学
作者
Randi Azmi,Shynggys Zhumagali,Helen Bristow,Shanshan Zhang,Aren Yazmaciyan,Anil Reddy Pininti,Drajad Satrio Utomo,Anand S. Subbiah,Stefaan De Wolf
标识
DOI:10.1002/adma.202211317
摘要
Abstract With the rapid rise in device performance of perovskite solar cells (PSCs), overcoming instabilities under outdoor operating conditions has become the most crucial obstacle toward their commercialization. Among stressors such as light, heat, voltage bias, and moisture, the latter is arguably the most critical, as it can decompose metal‐halide perovskite (MHP) photoactive absorbers instantly through its hygroscopic components (organic cations and metal halides). In addition, most charge transport layers (CTLs) commonly employed in PSCs also degrade in the presence of water. Furthermore, photovoltaic module fabrication encompasses several steps, such as laser processing, subcell interconnection, and encapsulation, during which the device layers are exposed to the ambient atmosphere. Therefore, as a first step toward long‐term stable perovskite photovoltaics, it is vital to engineer device materials toward maximizing moisture resilience, which can be accomplished by passivating the bulk of the MHP film, introducing passivation interlayers at the top contact, exploiting hydrophobic CTLs, and encapsulating finished devices with hydrophobic barrier layers, without jeopardizing device performance. Here, existing strategies for enhancing the performance stability of PSCs are reviewed and pathways toward moisture‐resilient commercial perovskite devices are formulated.
科研通智能强力驱动
Strongly Powered by AbleSci AI