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Functional Polymeric Micromaterials Based on Aggregation-Induced Emission Luminogens
Advanced Functional Materials ( IF 18.5 ) Pub Date : 2023-09-08 , DOI: 10.1002/adfm.202307267
Shusheng Chen 1 , Ting Han 2 , Ben Zhong Tang 3
Advanced Functional Materials ( IF 18.5 ) Pub Date : 2023-09-08 , DOI: 10.1002/adfm.202307267
Shusheng Chen 1 , Ting Han 2 , Ben Zhong Tang 3
Affiliation
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Aggregate materials have attracted tremendous attention because of their modified or totally different properties compared with their molecular counterparts. Among various mesoscopic aggregate materials, polymeric micromaterials possess the advantages of diverse structures and flexible manufacturing, enabling them to serve as excellent carriers for aggregation-induced emission luminogens (AIEgens) and good platforms for the research of aggregate science. In recent years, polymeric micromaterials constructed from AIEgens have witnessed rapid development and show great application potential in various fields, such as environmental sensing, multicolor displaying, and energy conversion. This review summarizes the recent progress on the design, preparation, structure, and applications of AIEgen-based polymeric micromaterials. According to the structure features, AIEgen-based polymeric micromaterials are divided into three categories, including microsphere, microfiber, and other-shaped microparticles. The most representative examples in each category are highlighted by focusing on their subdivision structures such as solid microsphere, porous microsphere, microcapsule, microfiber doped- or coated with AIEgens, and core–shell microfiber. Finally, the challenges and prospects in this research field are also discussed. It is hoped that this review can provide readers with an overall view on the development of AIEgen-based polymeric micromaterials and boost their further research.
中文翻译:
基于聚集诱导发射发光体的功能高分子微材料
聚集体材料因其与分子对应物相比具有改性或完全不同的性能而引起了极大的关注。在各种介观聚集材料中,高分子微材料具有结构多样、制造灵活的优势,使其成为聚集诱导发光发光体(AIEgens)的优良载体和聚集体科学研究的良好平台。近年来,由AIEgens构建的聚合物微材料发展迅速,在环境传感、多色显示、能量转换等领域显示出巨大的应用潜力。本文综述了基于AIEgen的聚合物微材料的设计、制备、结构和应用的最新进展。根据结构特征,AIEgen基聚合物微材料分为微球、微纤维和其他形状微颗粒三类。每个类别中最具代表性的例子都通过关注其细分结构来突出显示,例如实心微球、多孔微球、微胶囊、掺杂或涂覆AIEgens的微纤维以及核壳微纤维。最后,还讨论了该研究领域的挑战和前景。希望本文的综述能让读者对AIEgen基聚合物微材料的发展有一个整体的了解,并促进他们的进一步研究。
更新日期:2023-09-08
中文翻译:
基于聚集诱导发射发光体的功能高分子微材料
聚集体材料因其与分子对应物相比具有改性或完全不同的性能而引起了极大的关注。在各种介观聚集材料中,高分子微材料具有结构多样、制造灵活的优势,使其成为聚集诱导发光发光体(AIEgens)的优良载体和聚集体科学研究的良好平台。近年来,由AIEgens构建的聚合物微材料发展迅速,在环境传感、多色显示、能量转换等领域显示出巨大的应用潜力。本文综述了基于AIEgen的聚合物微材料的设计、制备、结构和应用的最新进展。根据结构特征,AIEgen基聚合物微材料分为微球、微纤维和其他形状微颗粒三类。每个类别中最具代表性的例子都通过关注其细分结构来突出显示,例如实心微球、多孔微球、微胶囊、掺杂或涂覆AIEgens的微纤维以及核壳微纤维。最后,还讨论了该研究领域的挑战和前景。希望本文的综述能让读者对AIEgen基聚合物微材料的发展有一个整体的了解,并促进他们的进一步研究。
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