Metal-Decorated Porous Organic Polymers: Bridged the Gap between Organic and Inorganic Scaffolds†

IF 5.5 1区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Chinese Journal of Chemistry Pub Date : 2024-08-08 DOI:10.1002/cjoc.202400386

Zhu Gao, Yufei Liu, Shaofei Wu, Juntao Tang, Kuanyu Yuan, Chunyue Pan, Guipeng Yu

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引用次数: 0

Abstract

Comprehensive Summary

Advanced functionalization-decorated porous organic polymers (POPs) are emerging as a prominent research focus, spanning from their construction to applications in gas storage and separation, catalysis, energy storage, electrochemistry, and other areas. Furthermore, the inherent organic nature, tailored pore structures, and adjustable chemical components of POPs offer a versatile platform for the incorporation of various metal active sites. Meticulously designed molecular building blocks can serve as organic ligands uniformly distributed throughout POPs, leading to the effective isolation of inorganic metal active sites at the molecular level. In this manner, POPs containing active metal centers bridge the gap between organic and inorganic scaffolds. This review aims to provide an overview of recent research progress on metal-decorated POPs, focusing on strategies for incorporating metal active sites into POPs and their applications in adsorption, separation, catalysis, and photoelectrochemistry. Finally, current challenges and future prospects are discussed for further research.

Key Scientists

Advanced functionalized porous organic polymers have become a new research hotspot, ranging from their construction to their use in gas storage and separation, catalysis, energy storage, electrochemistry, and other applications. In 2002, the McKeown group was the first to report phthalocyanine-based MPOPs with permanent porosity and a moderate surface area. In 2010, the Yu group prepared nanoporous polyporphyrin materials P(Fe-TTPP) from the metallated porphyrin with functionalized thiophenyl groups by the FeCl₃ catalyzed oxidation couple reaction showing the surface area of 1522 m²·g^–1. Subsequently, in 2013, the Deng group was the first to use metalated salens as the original building blocks for preparing MPOPs. The Morin group was the first to produce a series of ferrocene-based nanoporous frameworks via radical polymerization, with surface areas ranging from 385 to 899 m²·g^–1. In 2016, the Han group synthesized two N-pyridinylphenylcarbazole (PPC) ligands to produce a series of metalized polycarbazole networks. Recently, the Tan group reported a solvent-knitting hyper-cross-linking reaction to produce HUST-1, which contains a porphyrin unit. The porphyrin moiety provides a centered square-planar metal post-coordination site, resulting in the metalated HUST-1-Co, which exhibits high efficiency in the catalytic conversion of CO₂. Additionally, the Kegnæs group combined the decomposition of the palladium complex with an in situ catalyzed polymerization reaction, enabling the confinement of nascent Pd particles in the developing polymer network. This review focuses on recent research progress in metal-decorated POPs, emphasizing strategies for incorporating metal active sites into POPs and their applications.

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金属装饰多孔有机聚合物：弥合有机与无机支架之间的差距†...

先进的官能化装饰多孔有机聚合物（POPs）正在成为一个突出的研究重点，从其构造到在气体储存和分离、催化、能量储存、电化学和其他领域的应用，都有涉及。此外，持久性有机聚合物固有的有机性质、量身定制的孔隙结构以及可调节的化学成分，为各种金属活性位点的结合提供了一个多功能平台。精心设计的分子构件可作为有机配体均匀地分布在持久性有机污染物中，从而在分子水平上有效地分离出无机金属活性位点。这样，含有活性金属中心的持久性有机污染物就在有机和无机支架之间架起了一座桥梁。本综述旨在概述金属装饰持久性有机污染物的最新研究进展，重点介绍将金属活性位点纳入持久性有机污染物的策略及其在吸附、分离、催化和光电化学中的应用。先进的功能化多孔有机聚合物已成为一个新的研究热点，从其构造到在气体储存和分离、催化、储能、电化学和其他应用中的使用，不一而足。2002 年，McKeown 小组首次报道了具有永久孔隙率和适度比表面积的酞菁基 MPOP。2010 年，Yu 小组通过 FeCl3 催化氧化偶联反应，制备了具有官能化硫苯基基团的金属化卟啉的纳米多孔聚卟啉材料 P(Fe-TTPP)，比表面积达到 1522 m2-g-1。随后，在 2013 年，Deng 小组率先使用金属化卟啉作为制备 MPOPs 的原始构件。Morin 小组率先通过自由基聚合制备出一系列二茂铁基纳米多孔框架，其表面积在 385 至 899 m2-g-1 之间。2016 年，Han 小组合成了两种 N-吡啶基苯基咔唑（PPC）配体，制备出一系列金属化聚咔唑网络。最近，Tan 小组报告了一种溶剂编织超交联反应，生成了含有卟啉单元的 HUST-1。卟啉分子提供了一个居中的方形平面金属后配位位点，从而产生了金属化的 HUST-1-Co，在催化转化二氧化碳方面表现出很高的效率。此外，Kegnæs 小组还将钯络合物的分解与原位催化聚合反应相结合，使新生钯粒子被限制在发展中的聚合物网络中。本综述重点介绍金属装饰持久性有机污染物的最新研究进展，强调将金属活性位点纳入持久性有机污染物及其应用的策略。

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来源期刊

Chinese Journal of Chemistry 化学-化学综合

CiteScore

8.80

自引率

14.80%

发文量

422

审稿时长

1.7 months

期刊介绍： The Chinese Journal of Chemistry is an international forum for peer-reviewed original research results in all fields of chemistry. Founded in 1983 under the name Acta Chimica Sinica English Edition and renamed in 1990 as Chinese Journal of Chemistry, the journal publishes a stimulating mixture of Accounts, Full Papers, Notes and Communications in English.