卤化物
钙钛矿(结构)
光伏
极性(国际关系)
材料科学
化学计量学
化学物理
格子(音乐)
纳米技术
费米能级
光电子学
电子结构
金属
纳米尺度
带隙
离子
密度泛函理论
半导体
纳米电子学
科技与社会
凝聚态物理
薄膜
电子能带结构
电极
电子迁移率
锡
作者
Yalan Zhang,Guiming Fu,Zheng Liang,Sanwan Liu,Nam‐Gyu Park
摘要
ABSTRACT The remarkable rise of metal halide perovskite photovoltaics and optoelectronics has revealed semiconductive polarity as a central yet insufficiently understood determinant of device performance and stability. The soft ionic‐covalent lattice of halide perovskites hosts highly mobile ions and low‐formation‐energy defects that spontaneously self‐dope and dynamically shift the Fermi level. This unique defect‐lattice interplay profoundly affects band alignment, quasi‐Fermi‐level splitting, interfacial recombination, and ultimately the attainable open‐circuit voltage. In this review, we establish a hierarchical framework for polarity regulation spanning bulk defect thermodynamics, compositional tuning, additive coordination chemistry, and interfacial electronic design. We first elucidate how lattice geometry, orbital hybridization, and intrinsic defect equilibria dictate bulk carrier density and Fermi‐level position. We then discuss how targeted A/B/X‐site substitution, alloying strategies, and stoichiometric control modulate defect landscapes and stabilize desired electronic character. Based on these principles, we highlight how interfacial polarity engineering, including charge‐transfer interlayers and selective‐contact design, enables continuity of quasi‐Fermi levels and minimizes nonradiative losses at both p ‐ and n ‐type contacts. These insights unify defect physics and interfacial electrostatics, guiding polarity‐balanced, defect‐regulated perovskite optoelectronics, and highlighting opportunities in electrostatic modulation, heterovalent doping, surface reconstruction, and polarity engineering for perovskite solar cells.
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