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Synergistic Dual‐Interface Engineering in Perovskite Solar Cells via Chloramine Hydrochloride Molecular Bridges

Feiyi Zhou, Xu Zhang, Rujun Dai, Qingyue Guo, Yi Dong, Fanxiang Meng, Jun Wan, Zeyu Wang, Huajie Lyu, Chenghang Zheng, Qingquan He, Rui Wang, Peng Liu, Jun Pan, Xiang Gao

2025Angewandte Chemie International Edition14 citationsDOI

Abstract

Abstract High‐performance perovskite solar cells (PSCs) require synergistic passivation strategies to address defects at the electron transport layer (ETL)/perovskite interface, impacting both efficiency and long‐term stability. This study introduces chloramine hydrochlorides (CAHs) – 2‐Chloroethylamine Hydrochloride (CEA), Bis(2‐chloroethyl)amine Hydrochloride (BCEA), and Tris(2‐Chloroethyl)Amine Hydrochloride (TCEA) – as bifunctional molecular bridges to simultaneously passivate defects at both ETL (SnO 2 ) and perovskite interfaces while controlling crystallization. Density functional theory calculations showed that TCEA forms strong Sn─Cl bonds, enhancing Sn⁴ + coordination. In situ characterization revealed that TCEA accelerated perovskite formation, suppressed PbI 2 , and promoted larger grains, thus minimizing grain boundary defects. This leads to an improved electron extraction efficiency, prolonged hot‐carrier cooling, and a champion power conversion efficiency (PCE) of 25.25% (compared to 23.64% for controls), with negligible hysteresis and 90% PCE retention after 1000 h under ambient conditions. This study establishes a universal molecular design strategy for dual‐interface engineering in high‐efficiency and stable PSCs.

Topics & Concepts

Perovskite (structure)Dual (grammatical number)Interface (matter)ChloramineMaterials scienceChemical engineeringHydrochlorideChemistryComposite materialEngineeringOrganic chemistryMetallurgyChlorineLiteratureCapillary numberArtCapillary actionPerovskite Materials and ApplicationsConducting polymers and applicationsChalcogenide Semiconductor Thin Films