What drives porosity in aluminosilicate zeolites?

IF 2.6 3区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

CrystEngComm Pub Date : 2025-03-20 DOI:10.1039/D5CE00034C

Dries Vandenabeele, Anjul Rais, Christine Kirschhock and Eric Breynaert

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Abstract

Discovery of their commercial potential gave rise to a massive implementation of zeolites in industrial (petro-)chemical processes. Their robustness and molecular scale porosity in combination with acidic and/or ion exchange properties makes zeolites nearly indispensable for most of these applications. This highlight explores the origins of zeolite porosity. As microporosity is an inherent feature of the formed topology, we emphasize the link with phase selection. For zeolites, phase selection is driven by competition between water and framework elements to coordinate with extra-framework species. This competition is important in the final product, where such coordinations provide thermodynamic stability, as well as in the crystallization medium where supermolecular structrures can play a templating role. Synthesis experiments using hydrated silicate ionic liquids show that limited water availability prompts the formation of less porous (or even dense) phases, while moderate hydration supports the development of more open frameworks. Understanding these interactions is key to deepening the insight into zeolite genesis and can guide strategies for tailoring material properties for industrial applications.

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是什么驱动铝硅酸盐沸石的孔隙度？

由于其商业潜力的发现，沸石在工业（石油）化学过程中得到了广泛应用。沸石的坚固性、分子尺度孔隙度以及酸性和/或离子交换特性，使得沸石在这些应用中几乎不可或缺。这个亮点探讨了沸石孔隙的起源。由于微孔隙是形成的拓扑结构的固有特征，因此我们强调其与相选择的联系。对于沸石，相选择是由水和框架元素之间的竞争驱动的，以协调框架外的物种。这种竞争在最终产品中很重要，这种配位提供了热力学稳定性，以及在结晶介质中，超分子结构可以发挥模板作用。使用水合硅酸盐离子液体的合成实验表明，有限的水可用性促使形成较少多孔（甚至致密）的相，而适度的水化有助于形成更开放的框架。了解这些相互作用是加深对沸石成因的了解的关键，可以指导为工业应用量身定制材料特性的策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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