Maximizing Active Fe Species in ZSM-5 Zeolite Using Organic-Template-Free Synthesis for Efficient Selective Methane Oxidation

Overview

Journal J Am Chem Soc

Publisher American Chemical Society

Specialty Chemistry

Date 2023 Feb 14

PMID 36786783

Authors

Qingpeng Cheng

Guanna Li

Xueli Yao

Lirong Zheng

Junhu Wang

Abdul-Hamid Emwas

Pedro Castano

Javier Ruiz-Martinez

Yu Han

Affiliations

Soon will be listed here.

Abstract

The selective oxidation of CH in the aqueous phase to produce valuable chemicals has attracted considerable attention due to its mild reaction conditions and simple process. As the most widely studied catalyst for this reaction, Fe-ZSM-5 demonstrates high intrinsic activity and selectivity; however, Fe-ZSM-5 prepared using conventional methods has a limited number of active Fe sites, resulting in low CH conversion per unit mass of the catalyst. This study reports a facile organic-template-free synthesis strategy that enables the incorporation of more Fe into the zeolite framework with a higher dispersion degree compared to conventional synthesis methods. Because framework Fe incorporated in this way is more readily transformed into isolated extra-framework Fe species under thermal treatment, the overall effect is that Fe-ZSM-5 prepared using this method (Fe-HZ5-TF) has 3 times as many catalytically active sites as conventional Fe-ZSM-5. When used for the selective oxidation of CH with 0.5 M HO at 75 °C, Fe-HZ5-TF produced a high C oxygenate yield of 109.4 mmol g h (a HCOOH selectivity of 91.1%), surpassing other catalysts reported to date. Spectroscopic characterization and density functional theory calculations revealed that the active sites in Fe-HZ5-TF are mononuclear Fe species in the form of [(HO)Fe(IV)═O] bound to Al pairs in the zeolite framework. This differs from conventional Fe-ZSM-5, where binuclear Fe acts as the active site. Analysis of the catalyst and product evolution during the reaction suggests a radical-driven pathway to explain CH activation at the mononuclear Fe site and subsequent conversion to C oxygenates.

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