Top-down engineering of zeolite porosity

IF 40.4 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Chemical Society Reviews Pub Date : 2025-07-08 DOI:10.1039/d5cs00319a

Wieslaw J. Roth, Barbara Gil, Karolina A. Tarach, Kinga Góra-Marek

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Abstract

Synthetic zeolites present a near-ideal environment for catalytic conversion and separation of molecules. They have framework structures with discrete uniform micropores allowing selective processing and sorption based on the size and shape of molecules. Zeolites have been deployed in numerous industrial applications motivating continuous innovation efforts to synthesise new structures and pore systems. The conventional zeolite syntheses are carried out directly as hydrothermal bottom-up assemblies from molecular or amorphous precursors, producing robust hard-to-modify structures/crystals. To diversify zeolite structures, especially to alleviate diffusional limitations and active site accessibility, top-down modification approaches have been initiated. This article presents an overview of the various top-down methods for modifying already synthesised zeolite crystals or precursors to engineer additional porosity and functionality. They include: demetallation focused on Si and Al but also Ge and Ti, formation of micro/mesoporous hybrids by recrystallisation, mechanochemical methods, pore engineering with low-dimensional zeolite forms, especially 2D and nanozeolites, and treatments by microwaves, ultrasounds, plasma and lasers. The discussion presents illustrative examples of relevant properties, such as textural, acidic and catalytic, of materials obtained by the applied treatments. The methods and descriptors used to characterise changes in porosity are described in detail. An extended compilation of reported materials with textural properties is provided.

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沸石孔隙度自上而下的工程研究

合成沸石为分子的催化转化和分离提供了接近理想的环境。它们具有具有离散均匀微孔的框架结构，允许根据分子的大小和形状进行选择性处理和吸附。沸石已经应用于许多工业应用中，激发了不断创新的努力，以合成新的结构和孔隙系统。传统的沸石合成是由分子或无定形前体直接进行水热自下而上组装，产生坚固的难以修饰的结构/晶体。为了使沸石结构多样化，特别是为了减轻扩散限制和活性位点的可及性，人们开始采用自顶向下的改性方法。本文概述了各种自上而下的方法，用于修改已经合成的沸石晶体或前体，以设计额外的孔隙度和功能。它们包括：以硅和铝为重点的脱金属，也包括锗和钛，通过再结晶形成微/介孔杂化物，机械化学方法，低维沸石形式的孔隙工程，特别是二维和纳米沸石，以及微波，超声波，等离子体和激光处理。讨论给出了通过应用处理获得的材料的相关性质，如结构、酸性和催化性的说明性例子。详细描述了表征孔隙度变化的方法和描述符。提供了具有纹理特性的报告材料的扩展汇编。

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来源期刊

Chemical Society Reviews 化学-化学综合

CiteScore

80.80

自引率

1.10%

发文量

345

审稿时长

6.0 months

期刊介绍： Chemical Society Reviews is published by: Royal Society of Chemistry. Focus: Review articles on topics of current interest in chemistry; Predecessors: Quarterly Reviews, Chemical Society (1947–1971); Current title: Since 1971; Impact factor: 60.615 (2021); Themed issues: Occasional themed issues on new and emerging areas of research in the chemical sciences