钙钛矿(结构)
材料科学
光电子学
能量转换效率
费斯特共振能量转移
电压
紫外线
工作(物理)
接口(物质)
能量转换
频道(广播)
功率(物理)
化学物理
纳米技术
能量(信号处理)
太阳能
过程(计算)
图层(电子)
超短脉冲
能量转移
接受者
共振(粒子物理)
传输效率
理论(学习稳定性)
化学工程
堆栈(抽象数据类型)
压力(语言学)
产量(工程)
高效能源利用
溶解过程
八面体
高压
科技与社会
极化(电化学)
电荷(物理)
电解质
电子转移
作者
Xin Chen,Ping Xu,Qi Wang,Wei Hui,Ben Fan,Wuke Qiu,Lin Song,Xiaopeng Xu,Yihui Wu,Qiang Peng
摘要
ABSTRACT Perovskite solar cells (PSCs) offer high power conversion efficiencies (PCEs) but suffer from UV‐induced degradation, hindering their practical deployment. Here, we introduce a Förster resonance energy transfer (FRET) channel at the hole‐transport layer (HTL)/perovskite interface by incorporating the ultraviolet absorber N‐(2‐ethoxyphenyl)‐N’‐(2‐ethylphenyl)oxamide (UV‐312). Under UV irradiation, UV‐312 adopts an enol‐resonant configuration that facilitates ultrafast FRET (∼20 ps) to the interface. This process promotes charge separation and suppresses UV‐induced Pb–I bond dissociation, thereby preserving the [PbI 6 ] 4– octahedral framework and enhancing UV‐stress resilience. Moreover, the rigid, extended conjugation of UV‐312 mitigates MeO‐2PACz aggregation, optimizing interfacial energy‐level alignment and minimizing stress inhomogeneity. Consequently, the champion device (aperture area: 0.09 cm 2 ) achieves a remarkable PCE of 27.05% with a high open‑circuit voltage of 1.186 V and a minimal non‐radiative voltage loss of only 61 mV. Impressively, the performance scales to 25.08% for a 1 cm 2 PSC and 23.00% for a 12.96 cm 2 mini‑module, accompanied by robust operational stability under continuous light, heat, and UV stress. This work redefines UV absorbers as active energy‐management units, offering a unified approach to simultaneously address efficiency and stability issues in perovskite photovoltaics.
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