Molecular Weaving towards Metalloporphyrin Polymer Coatings with Integrated High Stiffness and Flexibility for Anti-SARS-CoV-2 Application

IF 6.4 1区化学 Q1 CHEMISTRY, INORGANIC & NUCLEAR

Inorganic Chemistry Frontiers Pub Date : 2025-10-07 DOI:10.1039/d5qi01837d

Xiaoman Yao, Jie Han, Xuanxu Chen, Caier Huang, Mingjin Shi, Qiuhua Wei, Xiaojie Ma, Qian-You Wang, Tao Wang, Yifa Chen, Bo Wang, Yaqian Lan

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Abstract

High stiffness and high flexibility are often considered as conflicting properties within polymers, which sets obstacles in developing next-generation materials such as coatings with high mechanical strength. We overcome this conflict by designing a series of metalloporphyrin polymers through an in-situ copolymerization strategy based on stiff porphyrin units and flexible thiourea linkers. Mechanically robust metalloporphyrin polymer coatings can be readily formed in place once their starting materials are coated on substrates such as cloth, fiber, paper cup, glass and metal foil. The coupling of stiffness with flexibility not only endows these properties of the metalloporphyrin polymer to the coated substrates, but also promises surface adaptability when applying onto a broad scope of materials. Modified with metal centers, anti-pathogenic functions for viruses like SARS-CoV-2 can be achieved when manufactured as mask coatings, holding promise in medical prevention and life protection.

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高刚度、高柔韧性金属卟啉高分子涂层的分子编织研究

高刚度和高柔韧性通常被认为是聚合物中相互冲突的特性，这为开发下一代材料（如具有高机械强度的涂层）设置了障碍。我们通过基于刚性卟啉单元和柔性硫脲连接剂的原位共聚策略设计了一系列金属卟啉聚合物，从而克服了这一冲突。机械坚固的金属卟啉聚合物涂层一旦将其起始材料涂在诸如布、纤维、纸杯、玻璃和金属箔等基材上，就可以很容易地在适当的位置形成。刚性与柔性的耦合不仅赋予了金属卟啉聚合物涂层基底的这些特性，而且在应用于广泛的材料时也保证了表面适应性。经金属中心修饰后，制成口罩涂层可实现对SARS-CoV-2等病毒的抗病毒功能，在医疗预防和生命保护方面前景广阔。

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