甲脒
材料科学
三碘化物
钙钛矿(结构)
能量转换效率
热稳定性
相(物质)
光活性层
化学工程
碘化物
纳米技术
混合太阳能电池
卤化物
光伏系统
偶极子
Crystal(编程语言)
菁
化学稳定性
光电子学
热致变色
碘化氢
光伏
热的
作者
Ying Wang,Lu Zhang,K. Q. Li,Yunfan Wang,Yiran Tao,Xinhui Lu,SaiWing Tsang,Hao‐Chung Kuo,Jiaxue You,Alex K. Y. Jen,Shengzhong “Frank” Liu
标识
DOI:10.1002/aenm.202504844
摘要
ABSTRACT Recent advances in formamidinium lead triiodide (FAPbI 3 ) solar cells have significantly improved their photoelectric conversion efficiency, positioning them as a leading candidate in third‐generation photovoltaics. However, their thermodynamic metastability—driven by phase transitions from photoactive α‐FAPbI 3 to inactive δ‐FAPbI 3 —causes efficiency decay, hindering long‐term stability and industrialization. This study introduces a bimolecular synergistic anchoring strategy to address these challenges: a multiscale molecular interlocking network is constructed using 4‐[3‐(trifluoromethyl)‐3H‐diazirin‐3‐yl]benzoic acid (HDA) and 2‐benzamidinyl‐5‐guanidinopentanoic acid (GS). HDA stabilizes formamidinium iodide (FAI) via carbene reactions, suppressing FA⁺ thermal escape, while GS binds under‐coordinated Pb 2 ⁺ through its high dipole moment, minimizing lead leakage. Leveraging structural homology, these dual passivators synergistically stabilize A‐site (FA⁺) and B‐site (Pb 2 ⁺) ions, forming a hydrogen‐bond network that optimizes crystal growth and enhances α‐FAPbI 3 phase stability and photothermal resilience. Perovskite solar cells (PSCs) optimized with HDA‐GS achieve a record power conversion efficiency of 26.07%, along with exceptional operational stability: unencapsulated devices retain 95% of initial efficiency after 1300 h at 85°C under nitrogen (thermal stability) and 91% after 1500 h of continuous light exposure (light stability). This work demonstrates that a multi‐scale molecular interlocking network effectively overcomes perovskite inherent instability, offering a scalable pathway to high‐performance, durable PSCs.
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