Structural Effect of Cu-Mn/Al2O3 Catalysts on Enhancing Toluene Combustion Performance: Molecular Structure of Polyols and Hydrothermal Treatment

Catalysts Pub Date : 2024-07-11 DOI:10.3390/catal14070443

Junjie Li, Wenjing Chen, Chenghua Xu, Xiaoxiao Hou, Xiaodong Hu

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Abstract

This study presents a series of Cu-Mn/Al2O3 catalysts prepared by the polyol method to improve the toluene combustion process. The catalytic activity evaluation results showed that the different polyols have a great influence on catalyst activity, in which the catalyst prepared with glycerol through a hydrothermal reaction at 90 °C displayed the highest catalytic activity. The lowest T90 and T50 values could be achieved by CMA-GL-90 with 260 and 237 °C, respectively. Moreover, the XRD and BET results showed that the hydrothermal treatment was more favorable with Cu-Mn crystal formation, and an abundance of mesopores remained in all catalysts with a high specific surface area from 94.37 to 123.03 m2·g−1. The morphology analysis results by SEM and TEM indicated that employing glycerol coupled with hydrothermal treatment at 90 °C could enhance the formation of CuMn2O4 spinel. The toluene catalytic combustion mechanism of Cu-Mn/Al2O3 catalysts was discussed based on XPS and H2-TPR, and a high atomic ratio of Mn3+ could be obtained with 51.03%, and the ratio of Oads/Olatt also increased to 2.85 in CMA-GL-90. The increase in Mn3+ species and oxygen vacancies on the surface of catalysts exhibited excellent activity and stability for toluene combustion. These findings offer valuable insights for optimizing the design and application of Cu-Mn/Al2O3 catalysts in addressing the catalytic oxidation reactions of organic volatile compounds.

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Cu-Mn/Al2O3 催化剂对提高甲苯燃烧性能的结构影响：多元醇的分子结构和水热处理

本研究采用多元醇法制备了一系列 Cu-Mn/Al2O3 催化剂，用于改善甲苯燃烧过程。催化活性评价结果表明，不同的多元醇对催化剂活性有很大影响，其中用甘油在 90 ℃ 下进行水热反应制备的催化剂显示出最高的催化活性。CMA-GL-90 的 T90 值和 T50 值最低，分别为 260 ℃ 和 237 ℃。此外，XRD 和 BET 结果表明，水热处理更有利于铜锰晶体的形成，所有催化剂中都保留了大量的中孔，比表面积从 94.37 到 123.03 m2-g-1 不等。SEM 和 TEM 的形貌分析结果表明，使用甘油并在 90 °C 下进行水热处理可促进 CuMn2O4 尖晶石的形成。基于 XPS 和 H2-TPR 对 Cu-Mn/Al2O3 催化剂的甲苯催化燃烧机理进行了探讨，结果表明，在 CMA-GL-90 中，Mn3+ 的原子比高达 51.03%，Oads/Olatt 比也增加到 2.85。催化剂表面 Mn3+ 物种和氧空位的增加，使其在甲苯燃烧中表现出优异的活性和稳定性。这些发现为优化 Cu-Mn/Al2O3 催化剂的设计和应用以解决有机挥发性化合物的催化氧化反应提供了宝贵的见解。

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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Catalysts

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