材料科学
钙钛矿(结构)
制作
二次谐波产生
卤化物
光电子学
纳米技术
微晶
光学
化学工程
无机化学
激光器
医学
化学
物理
替代医学
病理
工程类
冶金
作者
Jinjin Zhao,Yingjie Zhao,Yangwu Guo,Xiuqin Zhan,Jiangang Feng,Yue Geng,Meng Yuan,Xin Fan,Hanfei Gao,Lei Jiang,Yongli Yan,Yuchen Wu
标识
DOI:10.1002/adfm.202105855
摘要
Abstract Hybrid organic–inorganic metal‐halide perovskites with diverse structure tunability are promising for nonlinear‐optical (NLO) applications, such as frequency conversion and electro‐optic modulation. For integrated NLO devices, single‐crystalline perovskite micro‐ and nanostructures with high quality and multifunctionality are in high demand. However, the fabrication of single‐crystalline perovskites arrays is still challenging in regulating liquid dynamics and crystal growth simultaneously. Herein, a capillary‐bridge‐manipulated strategy is established to steer the dewetting process of microdroplets and provide spatial confinement for crystal growth. These 1D perovskite microwire arrays show regulated geometry, pure orientation, and single crystallinity. Chiral ammonium molecules are introduced into the metal‐halide octahedral quantum wells to break the centrosymmetry of the perovskite, allowing the perovskite to exhibit excellent second‐order NLO properties. The as‐prepared microwire arrays also demonstrate linearly polarized second harmonic generation and two‐photon fluorescence. Microwire arrays exhibit higher second harmonic conversion efficiency compared with their polycrystalline thin‐film counterparts. It is believed that this strategy for the fabrication of chiral perovskite microstructure arrays holds great promise for NLO integrated applications and opens up an avenue to explore multifunctional chiral perovskites.
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