钙钛矿(结构)
化学物理
材料科学
工作(物理)
相(物质)
不稳定性
拉伤
方向(向量空间)
相变
拉伸应变
接口(物质)
平面(几何)
极限抗拉强度
结构稳定性
理论(学习稳定性)
纳米技术
凝聚态物理
相对相位
能量转换效率
化学稳定性
作者
Chuwu Xing,Y W Li,Qinhui Bao,Miao He,Zhiqiang Lu,Yibin Zhang,Zhike Liu,Tianjin Zhang,D Q Wang
标识
DOI:10.1038/s41467-026-73739-0
摘要
The structural instability of formamidinium-based perovskite primarily originates from spontaneous α-to-δ phase transition. Although various suppression strategies have been proposed, developing a definitive solution remains challenging due to incomplete understanding of the physical mechanisms governing this phase transition. This work reveals that the coherent interface with tensile strain between perovskite α-phase (011) and δ-phase (110) planes acts as an active site for α-to-δ phase transition. Building on this insight, two-dimensional perovskitoid materials are introduced into the perovskite matrix, which strongly interact with the δ-phase (110) plane to form the 2D/δ interface. The large interfacial strain disrupts δ-phase orientation, suppresses the formation of α/δ transition interfaces, and thus enhances α-phase stability. This strategy enables FA-based perovskite solar cells to achieve an efficiency of 25.61%, with unencapsulated devices maintaining 90% initial efficiency after 1,000 h at 70% relative humidity. This work provides a mechanistic understanding and a universally applicable strategy to stabilize FA-based perovskites. Xing et al. report that the coherent interface with tensile strain between perovskite α-phase (011) and δ-phase (110) acts as an active site for α-to-δ phase transition. 2D perovskitoid materials are introduced to form the 2D/δ interfaces and enhance α-phase stability for efficient and stable solar cells.
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