Understanding the Fundamentals of Microporosity Upgrading in Zeolites: Increasing Diffusion and Catalytic Performances.

Zhengxing Qin,Xinmei Liu,Ovidiu Ersen,Yingxu Wei,Shutao Xu,Georgian Melinte,Tomáš Bučko,Yanfeng Shen,Valentin Valtchev,Michael Badawi,Shu Zeng,Svetlana Mintova,Zhongmin Liu,Zifeng Yan,Jean‐Pierre Gilson

doi:10.1002/advs.202100001

Abstract

Hierarchical zeolites are regarded as promising catalysts due to their well‐developed porosity, increased accessible surface area, and minimal diffusion constraints. Thus far, the focus has been on the creation of mesopores in zeolites, however, little is known about a microporosity upgrading and its effect on the diffusion and catalytic performance. Here the authors show that the “birth” of mesopore formation in faujasite (FAU) type zeolite starts by removing framework T atoms from the sodalite (SOD) cages followed by propagation throughout the crystals. This is evidenced by following the diffusion of xenon (Xe) in the mesoporous FAU zeolite prepared by unbiased leaching with NH4F in comparison to the pristine FAU zeolite. A new diffusion pathway for the Xe in the mesoporous zeolite is proposed. Xenon first penetrates through the opened SOD cages and then diffuses to supercages of the mesoporous zeolite. Density functional theory (DFT) calculations indicate that Xe diffusion between SOD cage and supercage occurs only in hierarchical FAU structure with defect‐contained six‐member‐ring separating these two types of cages. The catalytic performance of the mesoporous FAU zeolite further indicates that the upgraded microporosity facilitates the intracrystalline molecular traffic and increases the catalytic performance.

Highlights

Zeolites are crystalline aluminosilicates with unique framework topologies and adjustable acid properties widely used in catalysis, adsorption and separation
The dynamic evolution of the micro- and meso-porosity of FY zeolites can be revealed by electron tomography (3D-Transmission electron microscopy (TEM)), but 3D imaging of pores smaller than 2 nm is a difficult challenge for micron-sized zeolite crystals
The evolution of micropores and mesopores in hierarchical zeolites with the FAU-type framework structure are monitored by 3D-TEM and HP 129Xe NMR

Summary

Introduction

Zeolites are crystalline aluminosilicates with unique framework topologies and adjustable acid properties widely used in catalysis, adsorption and separation. The postsynthesis removal of framework atoms and the associated formation of mesopores, i.e., the creation of “highways” is already widely used to improve the intra-crystalline molecular traffic of reactants and products.[1] Recently, significant improvements in the design, synthesis, characterization and use of these hierarchical zeolites were made.[2,3,4,5,6] Despite such efforts, many important issues still need to be addressed. The mechanism of mesopore formation is not yet fully understood on a micro-scale.[7] various microscopy techniques enable to visualize mesoporosity at different length scales,[8, 9] the initial step of their formation, i.e., the removal of framework atoms and its consequences, is not yet fully understood.[10]

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