材料科学
钙钛矿(结构)
覆盖层
钝化
化学物理
异质结
光电子学
偶极子
费米能级
能量转换效率
光伏
表面状态
电子
钙钛矿太阳能电池
凝聚态物理
电子传输链
纳米技术
电子结构
插层(化学)
载流子寿命
发光二极管
载流子
化学工程
电极
激发态
密度泛函理论
作者
Prachtrakool Kooking,Nakorn Henjongchom,Chantiga Choochottiros,Ratchadaporn Supruangnet,Nopporn Rujisamphan,Thidarat Supasai
标识
DOI:10.1021/acsami.6c05326
摘要
High Resolution Image Download MS PowerPoint Slide Oxygen-vacancy defects in SnO x electron transport layers are a major source of interfacial recombination and instability in perovskite solar cells. Here, we introduce a bioderived dual interfacial strategy that regulates both defect states and interfacial energetics. Polyaniline-grafted chitin whiskers (CTW- g -PANI) coordinate with under-coordinated Sn sites, compensating oxygen-deficient states and inducing an upward shift of the SnO x Fermi level. The resulting interfacial dipole improves band alignment with the perovskite and facilitates electron extraction. In parallel, a thin polyaniline (PANI) overlayer modulates the perovskite surface electronic structure through coordination with under-coordinated Pb 2+ species, reducing trap-associated tail states and contributing to suppressed interfacial recombination. As a result, the dual-modified devices exhibit enhanced charge extraction and reduced trap density, delivering a power conversion efficiency of 17.73% compared to 14.46% for the untreated control. Nonencapsulated devices retain 93% of their initial efficiency after 30 days at 35% relative humidity, whereas the control retains only 80%. These findings demonstrate that the coordinated modulation of interfacial defect energetics and dipole formation enabled by the bioderived molecules plays a decisive role in stabilizing device operation and mitigating defect-mediated losses in perovskite photovoltaics.
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