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K+改性CuFe2O4催化剂微波脱硝性能OA

Microwave denitration performance of K+-modified CuFe2O4 catalyst

中文摘要英文摘要

采用溶胶-凝胶法在自制的吸波发热陶瓷表面制备了纳米Cu1-xKxFe2O4复合催化剂涂层,并在不同条件下(微波辐射功率0~50 W,反应温度250~600℃、氧气浓度0%~6%),研究了该催化剂直接催化分解NO气体的性能及影响其变化的规律;采用XRD、SEM、H2-TPR和O2-TPD等测试表征方法对该催化剂的相组成、微观结构及催化活性进行了分析与表征.研究结果表明:合Cu0.9K0.1Fe2O4催化活性最佳,当反应温度350℃,微波功率10 W,氧浓度4%条件下,NO转化率最高达到92.8%且具有良好的催化稳定性.掺杂一定量K+的Cu0.9K0.1Fe2O4催化剂能够促进氧空位的形成与增多,有利于催化反应的进行;在微波辐射的作用下,催化剂表面的氧空位与极性气体分子NO能够有效吸收微波能量,进而被活化,显著提升NO分解效率.

The nano Cu1-xKxFe2O4 composite catalyst coatings are fabricated on the surface of a self-made absorbing and heating ceramic via the sol-gel method.The performance of this catalyst in directly catalyzing the decomposition of NO gas and the rules influencing its changes are studied under different conditions(microwave radiation power of 0-50 W,reaction temperature of 250-600℃,and oxygen concentration of 0%-6%).The phase composition,microstructure,and catalytic activity of the catalyst are analyzed and characterized by XRD,SEM,H2-TPR,and O2-TPD testing methods.The results show that in the case of different K+doping amounts,Cu1-xKxFe2O4 catalysts all generate uniform nanocrystalline particles with a spinel structure.With the increase of K+,as well as the increase of reaction temperature and microwave power,the NO decomposition conversion efficiency of Cu1-xKxFe2O4 catalysts shows a trend of first increasing and then decreasing.The increase in oxygen concentration is beneficial for NO conversion.Cu0.9K0.1Fe2O4 catalyst reaches the highest NO conversion value of 92.8%,under the reaction temperature of 350℃,microwave power of 10 W,and oxygen concentration of 4%.The Cu0.9K0.1Fe2O4 catalyst doped with a certain amount of K+can promote the formation and increase of oxygen vacancies,which is conducive to the catalytic reaction.Meanwhile,under microwave radiation,the oxygen vacancies on the catalyst surface and polar gas molecules NO can absorb microwave energy and be activated,thereby enhancing the NO decomposition efficiency.

杜敬鑫;王浩;方伟;王柏涛

武汉理工大学 材料科学与工程学院,武汉 430070武汉理工大学 材料科学与工程学院,武汉 430070武汉理工大学 材料科学与工程学院,武汉 430070武汉理工大学 材料科学与工程学院,武汉 430070

通用工业技术

微波催化NO直接分解尖晶石催化剂纳米复合材料氧空位

microwave catalystNO direct decompositionspinelcatalystnano compositeoxygen vacancy

《材料工程》 2026 (6)

221-229,9

国家自然科学基金(50372033)

10.11868/j.issn.1001-4381.2025.000481

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