{"title":"增强微波辅助苯催化去除性能的 SiC/Co3O4 复合材料协同作用","authors":"Zhi Jiang, DongXu Fang, Haolin Luo, Zheng Ye, Hua Li, Wenfeng Shangguan","doi":"10.1016/j.mtchem.2024.102243","DOIUrl":null,"url":null,"abstract":"Microwave-assisted catalysis is a promising technique for enhancing catalytic reactions through selective heating, potentially leading to improved reaction rates and energy efficiency. However, understanding the complex interactions between microwave absorption and catalytic performance in composite catalysts remains a challenge. In this study, Cobalt oxide(CoO)/silicon carbide(SiC) composite catalysts with varying SiC content were synthesized and characterized to investigate the relationship between their microwave absorption properties and catalytic performance. Quantitative analysis revealed that SiC and CoO absorb microwave energy through relaxation polarization and magnetic loss mechanisms, respectively. Increasing SiC content enhanced the dielectric and magnetic loss capabilities of the composites, with the CoO/SiC composite containing 10 wt% SiC (CoO/SiC-10) exhibiting a dielectric loss tangent of 3.87 and a minimum reflection loss of −35dB. However, higher SiC content decreased the surface chemically adsorbed oxygen, surface oxygen mobility, and benzene adsorption capacity, weakening the catalytic activity under conventional heating. The CoO/SiC-10 sample achieved a significantly better balance between microwave absorption and catalytic performance, significantly outperforming the original CoO sample under microwave irradiation. These founding establishes a quantitative research methodology that correlates dielectric loss tangent, reflection loss, and other crucial parameters with microwave absorption performance and further catalytic properties, providing insights for the rational design of catalysts that optimize both microwave absorption and catalytic activity.","PeriodicalId":18353,"journal":{"name":"Materials Today Chemistry","volume":"33 1","pages":""},"PeriodicalIF":6.7000,"publicationDate":"2024-08-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Synergistic SiC/Co3O4 composites for enhanced microwave-assisted benzene catalytic removal performance\",\"authors\":\"Zhi Jiang, DongXu Fang, Haolin Luo, Zheng Ye, Hua Li, Wenfeng Shangguan\",\"doi\":\"10.1016/j.mtchem.2024.102243\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Microwave-assisted catalysis is a promising technique for enhancing catalytic reactions through selective heating, potentially leading to improved reaction rates and energy efficiency. However, understanding the complex interactions between microwave absorption and catalytic performance in composite catalysts remains a challenge. In this study, Cobalt oxide(CoO)/silicon carbide(SiC) composite catalysts with varying SiC content were synthesized and characterized to investigate the relationship between their microwave absorption properties and catalytic performance. Quantitative analysis revealed that SiC and CoO absorb microwave energy through relaxation polarization and magnetic loss mechanisms, respectively. Increasing SiC content enhanced the dielectric and magnetic loss capabilities of the composites, with the CoO/SiC composite containing 10 wt% SiC (CoO/SiC-10) exhibiting a dielectric loss tangent of 3.87 and a minimum reflection loss of −35dB. However, higher SiC content decreased the surface chemically adsorbed oxygen, surface oxygen mobility, and benzene adsorption capacity, weakening the catalytic activity under conventional heating. The CoO/SiC-10 sample achieved a significantly better balance between microwave absorption and catalytic performance, significantly outperforming the original CoO sample under microwave irradiation. 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引用次数: 0
摘要
微波辅助催化是一种很有前途的技术,可通过选择性加热提高催化反应,从而提高反应速率和能效。然而,了解复合催化剂中微波吸收与催化性能之间复杂的相互作用仍然是一项挑战。本研究合成并表征了不同碳化硅含量的氧化钴(CoO)/碳化硅(SiC)复合催化剂,以研究其微波吸收特性与催化性能之间的关系。定量分析发现,SiC 和 CoO 分别通过弛豫极化和磁损耗机制吸收微波能量。提高 SiC 含量可增强复合材料的介电损耗和磁损耗能力,含 10 wt% SiC 的 CoO/SiC 复合材料(CoO/SiC-10)的介电损耗正切为 3.87,最小反射损耗为 -35dB。然而,较高的 SiC 含量会降低表面化学吸附氧、表面氧迁移率和苯吸附能力,从而削弱常规加热条件下的催化活性。CoO/SiC-10 样品在微波吸收和催化性能之间取得了更好的平衡,在微波辐照下明显优于原始 CoO 样品。这些研究成果建立了一种定量研究方法,将介质损耗正切、反射损耗和其他关键参数与微波吸收性能和进一步的催化性能联系起来,为合理设计同时优化微波吸收和催化活性的催化剂提供了启示。
Synergistic SiC/Co3O4 composites for enhanced microwave-assisted benzene catalytic removal performance
Microwave-assisted catalysis is a promising technique for enhancing catalytic reactions through selective heating, potentially leading to improved reaction rates and energy efficiency. However, understanding the complex interactions between microwave absorption and catalytic performance in composite catalysts remains a challenge. In this study, Cobalt oxide(CoO)/silicon carbide(SiC) composite catalysts with varying SiC content were synthesized and characterized to investigate the relationship between their microwave absorption properties and catalytic performance. Quantitative analysis revealed that SiC and CoO absorb microwave energy through relaxation polarization and magnetic loss mechanisms, respectively. Increasing SiC content enhanced the dielectric and magnetic loss capabilities of the composites, with the CoO/SiC composite containing 10 wt% SiC (CoO/SiC-10) exhibiting a dielectric loss tangent of 3.87 and a minimum reflection loss of −35dB. However, higher SiC content decreased the surface chemically adsorbed oxygen, surface oxygen mobility, and benzene adsorption capacity, weakening the catalytic activity under conventional heating. The CoO/SiC-10 sample achieved a significantly better balance between microwave absorption and catalytic performance, significantly outperforming the original CoO sample under microwave irradiation. These founding establishes a quantitative research methodology that correlates dielectric loss tangent, reflection loss, and other crucial parameters with microwave absorption performance and further catalytic properties, providing insights for the rational design of catalysts that optimize both microwave absorption and catalytic activity.
期刊介绍:
Materials Today Chemistry is a multi-disciplinary journal dedicated to all facets of materials chemistry.
This field represents one of the fastest-growing areas of science, involving the application of chemistry-based techniques to the study of materials. It encompasses materials synthesis and behavior, as well as the intricate relationships between material structure and properties at the atomic and molecular scale. Materials Today Chemistry serves as a high-impact platform for discussing research that propels the field forward through groundbreaking discoveries and innovative techniques.