银/含氧酸银等离子共振催化剂可见光催化还原二氧化碳的催化行为及反应机理

项目名称： 银/含氧酸银等离子共振催化剂可见光催化还原二氧化碳的催化行为及反应机理

项目编号： No.21477117

项目类型： 面上项目

立项/批准年度： 2015

项目学科： 化学工业

项目作者： 宋爽

作者单位： 浙江工业大学

项目金额： 85万元

中文摘要： 研制开发高效可见光驱动催化剂进行CO2光催化还原对解决环境污染和能源短缺问题具有重要的科学意义和应用价值。本项目旨在合成新型银/含氧酸银等离子共振催化剂，并将其应用于液/固及气/固体系中CO2的高效还原，该项目的深入研究迄今尚属空白。通过调节制备参数并结合各种催化剂表征手段，建立银/含氧酸银等离子共振催化材料的有效合成方法，探明制备方法与催化剂物理化学性质之间的关系；调控催化剂的组成、晶型、结构、形貌等物性，确定其与材料内电荷传递过程及光催化还原CO2的活性，选择性，寿命之间的关系；构建气/固和液/固光催化体系，优化工艺参数，以期提高目标产物生成的量子效率和能量效率，并探明不同反应体系中可见光催化还原CO2过程中的界面过程及CO2的还原途径。本项目不仅为制备新型光催化材料提供一条崭新的途径，也可促进化学、材料、环境和能源等学科的交叉融合，有重要的学术意义和潜在的应用价值。

中文关键词： 光催化还原二氧化碳；银/含氧酸银；可见光；表面等离子共振；机理

英文摘要： The development of visible light driven catalysts for effective photocatalytic reduction of CO2 has scientific significance and application value to solve the problem of environmental pollution and energy crisis. Considering the low quantum yield and turnover number of traditional semiconcuctors in photocatalytic reduction of CO2 under visible light irradiation, this project aims at synthesizing plasmonic Ag/silver oxysalt materials for effectively photoreducing the CO2 in both solid-liquid and solid-gas reaction systems. To the best of our knowledge, the subject has rarely been studied in depth to date. By adjusting the preparing variables, the effective methods for synthesizing Ag/silver oxysalt photocatalysts are presented with the help of catalyst characterization, and the correlation between the physicochemical properties of the catalysts and the preparing methods is established. Moreover, the dependence of the activity, selectivity and stability during CO2 photoreduction and the charge transfer in materials on the physical-chemical properties of catalysts such as composition, crystal structure, morphology and spatial structure is explored. Two types of photocatalytic systems, including solid-liquid and solid-gas mode, are used to optimize the major operating parameters, in an attempt to increase the quantum yield and energy returned on energy invested of photocatalytic reduction of CO2 under visible light irridiation. Meanwhile, the interface performance and the reaction mechanism of photocatalytic reduction of CO2 in various reaction systems are investigated. The project, with significant academic value and potential application, will not only provide an innovative approach for the design and preparation of new photocatalytic materials, but also contribute to the cross-integration of the disciplines of chemistry, materials, environment and energy.

英文关键词： photocatalytic reduction of CO2;Ag/silver oxysalt;visible light;surface plasmonic resonance;mechanism