材料科学
钙钛矿(结构)
纳米技术
成核
晶界
可扩展性
基质(水族馆)
同种类的
能量转换效率
微观结构
图层(电子)
可穿戴技术
结晶
光伏系统
工程物理
表面能
可穿戴计算机
薄膜
能量转换
高效能源利用
柔性电子器件
计算机科学
耐久性
太阳能
作者
Yì Wáng,Xianghua Liu,Qiyuan Xia,Jinuo Huang,Jiayu Li,Yuyang Chen,Zeyuan Hu,Qifan Xue,Dongxiang Luo,Muhammad Bilal Khan Niazi,Xiaotian Hu,Yonggang Min
摘要
ABSTRACT Flexible perovskite solar cells (F‐PSCs) have emerged as a forefront technology in next‐generation photovoltaics, combining lightweight design, mechanical flexibility, and low‐temperature solution processability. Over the past decade, their power conversion efficiency (PCE) has dramatically improved from 2.62% to beyond 26%. This review provides a comprehensive summary of these developments. We begin by analyzing the crystallization kinetics of perovskite thin films, focusing on both homogeneous and heterogeneous nucleation pathways as interpreted through the LaMer growth model. Subsequently, we discuss substrate engineering, emphasizing polymeric and novel flexible substrates that dictate film quality and mechanical reliability. Perovskite layer optimization strategies are then examined, including microstructure regulation, defect passivation, and stress‐management approaches achieved via grain boundary modulation and multifunctional interfacial buffer layers. Furthermore, we highlight the emerging self‐healing concept, which leverages both physical mechanisms and chemical strategies to enhance durability under repeated mechanical deformation. Finally, we evaluate recent progress in device integration and large‐area scalable manufacturing, outlining key opportunities and remaining challenges for commercialization. By consolidating these insights, this review establishes a coherent framework for improving the structural resilience, operational stability, and scalability of F‐PSCs, thereby advancing their transition toward practical, flexible, and wearable energy applications.
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