材料科学
阴极
钙钛矿(结构)
图层(电子)
镱
化学工程
锡
工作职能
缓冲器(光纤)
兴奋剂
金属
光电子学
无机化学
有效核电荷
光伏系统
钙钛矿太阳能电池
纳米技术
电子
活动层
工作(物理)
螯合作用
作者
Xiaoxue Wang,Chenwu Zeng,Zhiqiang Yang,Chuan Luo,Jialun Jin,Hengqi Huang,Zhengyu Xiao,Hangyu Zhou,Junyu Qu,Zeyu Zhang,Shenghan Wu,Yong Li,Chao Ding,Cong Chen,C.M. Wang,Chen Yin,Sai Bai,Hui Li,Shengqiang Ren,Dewei Zhao
摘要
ABSTRACT Tin (Sn)‐based perovskite solar cells (PSCs) are promising candidates for low‐toxicity photovoltaics. However, their performance remains limited by interfacial energy losses and cathode degradation. Here, we report a facile strategy of adopting ytterbium acetylacetonate (Yb(acac) 3 ) as a solution‐processed cathode buffer layer (CBL) to regulate the C 60 /Cu interface in Sn‐based PSCs. The introduction of Yb(acac) 3 improves energy‐level alignment, suppresses charge accumulation and recombination, and facilitates electron extraction. Meanwhile, Yb(acac) 3 forms a chemically anchored interlayer with C 60 through π – π interactions, and its hydrophobic chelate structure hinders moisture ingress and iodide‐ion migration, thereby enhancing the corrosion resistance of the Cu electrode. These interfacial effects are consistent with the strong Lewis acidity and coordination capability of Yb 3+ , which support stable interfacial binding and modified charge transport at the cathode interface. As a result, the optimized Sn‐based PSCs deliver a champion efficiency of 14.92% together with substantially improved stability, maintaining 92% of the initial efficiency after 3000 h in N 2 and ∼85% after 350 h of continuous illumination in ambient air. This work provides an acetylacetonate‐based interfacial engineering strategy for achieving high‐performance Sn‐based PSCs.
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