分层多孔聚乙炔网络:高效去除水中双酚 A 的吸附性光催化剂

David Šorm, Jiří Brus, Albin Pintar, Jan Sedláček and Sebastijan Kovačič*, 
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摘要

在本文中,我们报告了一系列在高内相乳液(HIPEs)中通过链生长插入配位聚合形成的功能化聚乙炔类网络。所有聚合 HIPEs(polyHIPEs)都含有由微孔、中孔和大孔系统组成的分层结构三维互联多孔框架,因而具有极高的比表面积(高达 1055 m2-g-1)和超过 95% 的总孔隙率。将π-共轭结构和分层多孔结构结合在一种材料中,使这些聚乙炔聚HIPE 能够用作吸附型光催化剂,去除水中的化学污染物。所有聚乙炔聚HIPE 在吸附水中的双酚 A(高达 48%)以及随后的光催化降解方面都表现出很高的效率。令人惊讶的是,高吸附容量并没有影响光催化效率(高达 58%)。相反,这种双重功能似乎很有前途,因为一些聚乙炔聚 HIPE 通过吸附-光氧化机制几乎完全去除了水中的双酚 A(97%)。此外,聚乙炔骨架中极性官能侧基的存在似乎也改善了聚乙炔网络与双酚 A 水溶液的接触,从而更容易吸附双酚 A 并使其氧化,这弥补了某些网络较低的比表面积,即 3-乙炔基苯酚和 3-乙炔基苯胺聚乙炔聚HIPE 的比表面积分别为 471 和 308 m2-g-1。
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Hierarchically Porous Polyacetylene Networks: Adsorptive Photocatalysts for Efficient Bisphenol A Removal from Water

In this article, we report a series of functionalized polyacetylene-type networks formed by chain-growth insertion coordination polymerization in high internal phase emulsions (HIPEs). All polymerized HIPEs (polyHIPEs) contain a hierarchically structured, 3D-interconnected porous framework consisting of a micro-, meso- and macropore system, resulting in exceptionally high specific surface areas (up to 1055 m2·g–1) and total porosities of over 95%. The combination of π-conjugated and hierarchically porous structure in one material enabled the use of these polyacetylene polyHIPEs as adsorptive photocatalysts for the removal of chemical contaminants from water. All polyacetylene polyHIPEs demonstrated high efficiency in the adsorption of bisphenol A from water (up to 48%) and the subsequent photocatalytic degradation. Surprisingly, high adsorption capacity did not affect the photocatalytic efficiency (up to 58%). On the contrary, this dual function seems to be very promising, as some polyacetylene polyHIPEs almost completely removed bisphenol A from water (97%) through the adsorption-photooxidation mechanism. It also appears that the presence of polar functional side groups in the polyacetylene backbone improves the contact of the polyacetylene network with the aqueous bisphenol A solution, which can thus be more easily adsorbed and subsequently oxidized, compensating for the lower specific surface area of some networks, namely, 471 and 308 m2·g–1 in the case of 3-ethynylphenol- and 3-ethynylaniline-based polyacetylene polyHIPEs, respectively.

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