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光催化纸的孔隙结构对挥发性有机化合物分解的影响。

Effect of void structure of photocatalyst paper on VOC decomposition.

作者信息

Fukahori Shuji, Iguchi Yumi, Ichiura Hideaki, Kitaoka Takuya, Tanaka Hiroo, Wariishi Hiroyuki

机构信息

Department of Forest and Forest Products Sciences, Graduate School of Bioresource and Bioenvironmental Sciences, Kyushu University, Fukuoka 812-8581, Japan.

出版信息

Chemosphere. 2007 Feb;66(11):2136-41. doi: 10.1016/j.chemosphere.2006.09.022. Epub 2006 Dec 12.

Abstract

TiO2 powder-containing paper composites, called TiO2 paper, were prepared by a papermaking technique, and their photocatalytic efficiency was investigated. The TiO2 paper has a porous structure originating from the layered pulp fiber network, with TiO2 powders scattered on the fiber matrix. Under UV irradiation, the TiO2 paper decomposed gaseous acetaldehyde more effectively than powdery TiO2 and a pulp/TiO2 mixture not in paper form. Scanning electron microscopy and mercury intrusion analysis revealed that the TiO2 paper had characteristic unique voids ca. 10 microm in diameter, which might have contributed to the improved photocatalytic performance. TiO2 paper composites having different void structures were prepared by using beaten pulp fibers with different degrees of freeness and/or ceramic fibers. The photodecomposition efficiency was affected by the void structure of the photocatalyst paper, and the initial degradation rate of acetaldehyde increased with an increase in the total pore volume of TiO2 paper. The paper voids presumably provided suitable conditions for TiO2 catalysis, resulting in higher photocatalytic performance by TiO2 paper than by TiO2 powder and a pulp/TiO2 mixture not in paper form.

摘要

通过造纸技术制备了含二氧化钛粉末的纸复合材料,即二氧化钛纸,并对其光催化效率进行了研究。二氧化钛纸具有源自层状纸浆纤维网络的多孔结构,二氧化钛粉末分散在纤维基质上。在紫外线照射下,二氧化钛纸比粉末状二氧化钛和非纸状的纸浆/二氧化钛混合物更有效地分解气态乙醛。扫描电子显微镜和压汞分析表明,二氧化钛纸具有直径约10微米的独特特征孔隙,这可能有助于提高光催化性能。通过使用具有不同游离度的打浆纸浆纤维和/或陶瓷纤维制备了具有不同孔隙结构的二氧化钛纸复合材料。光分解效率受光催化剂纸的孔隙结构影响,乙醛的初始降解速率随二氧化钛纸总孔体积的增加而增加。纸孔隙大概为二氧化钛催化提供了合适的条件,导致二氧化钛纸的光催化性能高于二氧化钛粉末和非纸状的纸浆/二氧化钛混合物。

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