TiCl4-O2体系高温反应制备超细TiO2光催化材料的研究

无机材料学报, 1999, 14(5): 717-725.

TiCl₄-O₂体系高温反应制备超细TiO₂光催化材料的研究

施利毅 , 李春忠 , 房鼎业 , 张剑平 , 朱以华 , 陈爱平

1.1. 华东理工大学化工系

上海 200237

2. 2. 华东理工大学技术化学物理研究所

上海 200237

1.1. Institute of Technical Chemistry and Physics

East University of Science TechnologyShanghai 200237 China

2. 2. Department of Chemical Engineering

East University of Science Technology.Shanghai 200237 China

3. 3. School of Chemistry and Chemical Engineering Shanghai 200072, China

关键词：光催化材料 , null , null , null , null

Ultrafine Titania Photocatalytic Materials Synthesized by High Temperature Reaction in TiCl₄-O₂ System

SHI Li-Yi , Li Chun-Zhong , FanG Ding-Ye , ZHANG Jian-Ping , ZHU Yi-Hua , CHEN Ai-Ping

Keywords： photocatalytic materials, titania, ultrafine particle, aerosol, dyeing wastewater , 二氧化钛 , 超细粒子 , 气溶胶 , 染料废水

高温管式气溶胶反应器中，利用ＴｉＣｌ_４气相氧化制备超细ＴｉＯ_２光催化材料，研究了停留时间和反应温度对粒子形态的影响．结果表明ＴｉＯ_２粒度随停留时间延长和反应温度升高而增大；金红石相含量随停留时间延长而增加，当反应温度１３００℃时，粒子中金红石含量出现最大值．以偶氮染料活性艳红Ｘ－３Ｂ为模拟废水；考察粒子光催化活性．光催化活性与粒径和晶型等形态指标有关，等效粒径３６．４ｎｍ、金红石含量１８９７％ＴｉＯ_２的活性高于商品Ｐ２５和ＳＨ－１．

Ultrafine titania particles were synthesized by the gas-phase oxidation of titanium tetrachloride in a high temperature tubular aerosol
flow reactor. The measurement of EDS, TG-DTA, TEM, XRD and BET surface area was used to characterize the particles. The effect of residence time
and reaction temperature on the morphology of titania particles was investigated. The results showed the average particle size of titania
became larger and rutile weight fraction increased as the residence time increased, and the maximum rutile weight fraction was attained at 1300℃
and the particle size increased with increasing temperature. The prepared particles and commercial TiO₂were employed for photocatalytic
degradation of azo dye active red X--3B in aerated solution. The results showed that the photoactivity of the titania particles of average size
35.3nm and 18.97% rutile fraction was higher than that of P25 and SH--1.

参考文献

[1]

Ollis D F, Pelizzetti E, Serpone N. Photocatalysis Fundamentals and Applications. New York: John Wiley, 1994
2 Okamoto K, Yamamoto Y, Tanaka H, et al. Bull. Chem. Soc. Jpn., 1985, 58: 2015--2022
3 Pelizzetti E, Minero C. Comments Inorg. Chem., 1993, 15 (5,6): 297--337
4 Sclafani A, Palmisano L, Schiavello M. J. Phys. Chem., 1990, 94: 829--832
5 陈士夫，赵梦月，陶跃武. 化学工业与工程， 12 (2): ?-8
6 施利毅，华~~彬，张剑平. 功能材料， 1998， 29 (2): 136--139
7 施利毅，李春忠，房鼎业. 化工生产与技术， 1997， (4): 1--5,10
8 Spurr R A, Myers H. Anal. Chem., 1957, 29: 760--762
9 程虎民，马季铭，赵振国等. 高等学校化学学报， 1996， 17 (6): 833--837
10 Kobata A, Kusakabe K, Morooka S. AIChE J., 1991, 37 (3): 347--359
11 Mackenzie K. Trans J. Brit. Ceram. Soc., 1975, 74: 29--34
12 Yang G X, Zhuang H R, Biswas P. Nanostructured Materials, 1996, 7 (6): 675--689
13 Spadaro J T, Isabelle L, Ranganathan V. Environ. Sci. Technol., 1994, 28: 1389--1393
14 Zhao M Y, Chen S F, Tao Y W. J. Chem. Tech. Biotechnol., 1995, 64: 339--344

上一张下一张

计量

下载量()
访问量()

作者相关

文章评分

您的评分：
1

0%
2

0%
3

0%
4

0%
5

0%

材料期刊网