木质活性碳纤维负载Mn掺杂纳米TiO2复合材料的制备及其吸附-光催化活化机理的研究

项目名称： 木质活性碳纤维负载Mn掺杂纳米TiO2复合材料的制备及其吸附-光催化活化机理的研究

项目编号： No.31270607

项目类型： 面上项目

立项/批准年度： 2013

项目学科： 农业科学

项目作者： 马晓军

作者单位： 天津科技大学

项目金额： 70万元

中文摘要： 光催化氧化技术作为解决室内空气污染最有效的手段，其光催化剂表面修饰及其载体的选择已成为该项技术进行室内空气净化的关键。本课题以水热合成Mn掺杂纳米TiO2作为光催化剂，以木材等生物质资源为主要原料制备的木质活性碳纤维作为载体，以负载工艺将二者复合成吸附-光催化材料。项目将主要研究Mn掺杂因素对纳米TiO2复合材料电子结构、光学系数和晶格常数变化的微观机制；探究载体木质活性碳纤维的孔隙调控机制和活化反应机理；分析木质活性碳纤维负载Mn掺杂纳米TiO2的吸附-光催化活性机理；模拟吸附-光催化复合材料对甲醛的动态吸附降解过程，建立其进行室内空气净化的有效模式。项目的研究实现了光催化复合材料在可见光及紫外光的双重吸附催化降解功能，提高了生物质资源的利用率和附加值，开创了生物质资源的应用领域和途径，也为功能化木质碳材料的研究及其在吸附-光催化复合材料方面的应用提供理论基础和科学依据。

中文关键词： 木质活性炭纤维；二氧化钛；Mn掺杂；吸附；光催化活性机理

英文摘要： Photo-catalysis oxidation technology has become the most effective way in preventing indoor air pollution. It is the key for the surface modification of photocatalyst and the choice of the carrier in photo-catalysis oxidation technology. In the project, Mn doped nano-TiO2 prepared by the hydrothermal synthesis as the photocatalyst, wood-based activated carbon fibers prepared from biomass resources as the carrier, which will be prepared adsorption-photocatalytic materials by loading technology. The main content including: study on micro-mechanisms of the variation of electronic structure, optical coefficient and lattice parameter of nano-TiO2 composites because of Mn doped factors; investigate on pore control and activition mechanism of wood activated carbon fibers; analysis on adsorption-photocatalytic activity mechanism of Mn-doped nano-TiO2 loaded on wood-based activated carbon fibers; simulate on the dynamic adsorption degradation process of formaldehyde in order to establish the effective pattern of adsorption-photocatalysis composite materials for indoor air purification. The research could achieve double adsorption-catalytic degradation function of the composite photocatalyst under visible and UV light, improve the biomass resource utilization and value-added, create news application fields and the way of

英文关键词： wood-based activated carbon fiber；TiO2；Mn doped；adsorption；photocatalytic activity mechanism