CuO修饰TiO2纳米管的沉积-沉淀法制备及其催化CO氧化性能

材料导报, 2014, 28(12): 1-3.

CuO修饰TiO2纳米管的沉积-沉淀法制备及其催化CO氧化性能

田晶 ^1, , 王雪 ^2, , 韩骐伟 ^3, , 赵景涛 ^4, , 黄唯平 ^5, , 朱宝林 ^6,

1.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

2.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

3.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

4.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

5.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

6.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

基金项目: 国家大学生创新性实验计划(111005510) 天津市自然科学基金(13JCQNJC02000) 国家自然科学基金(21373120,21301098)

关键词：钛酸纳米管 , 氧化铜 , 沉积-沉淀法 , 催化CO氧化

Preparation of Copper Oxide Modified TiO2 Nanotubes by Deposition-Precipitation Method and Their Catalytic Activity for CO Oxidation

TIAN Jing ^1, , WANG Xue ^2, , HAN Qiwei ^3, , ZHAO Jingtao ^4, , HUANG Weiping ^5, , ZHU Baolin ^6,

1.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

2.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

3.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

4.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

5.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

6.南开大学化学系,金属与分子基材料化学天津市重点实验室,天津300071

Keywords： hydrogen , titanate , nanotubes , CuO

以钛酸纳米管和Cu(NO3)2为前驱体,采用沉积-沉淀法制备CuO修饰TiO2纳米管(CuO/TiO2 NTs).通过TEM(透射电子显微镜)、XRD(X射线衍射)和XPS(X射线光电子能谱)表征材料的结构,并研究制备过程中pH值对所得CuO/TiO2 NTs催化CO氧化活性的影响.研究表明,通过沉积-沉淀法可以制备高活性的CuO/TiO2NTs,随溶液的pH值升高,铜的负载量变少,而且不易被还原的二价铜含量升高,导致催化剂的活性变差.

参考文献

[1]	Larsson PO.;Andersson A. .Complete oxidation of CO, ethanol, and ethyl acetate over copper oxide supported on titania and ceria modified titania[J].Journal of Catalysis,1998(1):72-89.
[2]	Zheng XC;Wu SH;Wang SP;Wang SR;Zhang SM;Huang WP .The preparation and catalytic behavior of copper-cerium oxide catalysts for low-temperature carbon monoxide oxidation[J].Applied Catalysis, A. General: An International Journal Devoted to Catalytic Science and Its Applications,2005(1/2):217-223.
[3]	Zhou H B;Huang Z;Sun C et al.Catalytic decomposition of N2O over CuxCe1-xOy mixed oxides[J].Applied Catalysis B:Environmental,2012,125:492.
[4]	Cao J L;Wang Y;Zhang T Y et al.Preparation,characterization and catalytic behavior of nanostructured mesoporous CuO/Ce0.s Zr0.2O2 catalysts for low-temperature CO oxidation[J].Applied Catalysis B:Environmental,2008,78(1-2):120.
[5]	Xu B;Dong L;Chen Y .Influence of CuO loading on dispersion and reduction behavior of CuO/TiO2 (anatase) system[J].Journal of the Chemical Society Faraday Transactions,1998,94(13):1905.
[6]	Bond G C;Namijo S N;Wakeman J S .Thermal analysis of catalyst precursors:Part 2.Influence of support and metal precursor on the reducibility of copper catalysts[J].Journal of Molecular Catalysis,1991,64(03):305.
[7]	Stangland EE.;Andres RP.;Delgass WN.;Stavens KB. .Characterization of gold-titania catalysts via oxidation of propylene to propylene oxide[J].Journal of Catalysis,2000(2):332-347.
[8]	Chary KVR;Sagar GV;Naresh D;Seela KK;Sridhar B .Characterization and reactivity of copper oxide catalysts supported on TiO2-ZrO2[J].The journal of physical chemistry, B. Condensed matter, materials, surfaces, interfaces & biophysical,2005(19):9437-9444.
[9]	Haruta M;Ueda A;Tsubota S et al.Low-temperature catalytic combustion of methanol and its decomposed derivatives over supported gold catalysts[J].Catalysis Today,1996,29(1-4):443.
[10]	Xi Liu;Thomas F. Jaramillo;Andrei Kolmakov .Synthesis of Au nanoclusters supported upon a TiO_2 nanotube array[J].Journal of Materials Research,2005(5):1093-1096.
[11]	Zhu Baolin;Guo Qi;Huang Xueliang et al.Characterization and catalytic performance of TiO2 nanotubes-supported gold and copper particles[J].Journal of Molecular Catalysis A:Chemical,2006,249(1-2):211.
[12]	Zhu B L;Zhang X X;Wang S R et al.Synthesis and catalytic performance of TiO2 nanotubes-supported copper oxide for low-temperature CO oxidation[J].Microporous and Mesoporous Materials,2007,102(1-3):333.
[13]	Sun X M;Li Y D .Synthesis and characterization of ion-exchangeable titanate nanotubes[J].Chemistry-A European Journal,2003,9(10):2229.
[14]	Francisco M S P;Mastelaro V R;Nascente P A P et al.Activity and characterization by XPS,HR-TEM,Raman spectroscopy,and BET surface area of CuO/CeO2-TiO2 catalysts[J].Journal of Physical Chemistry B,2001,105(43):10515.
[15]	Melian-Cabrera I.;Granados ML.;Fierro JLG. .Bulk and surface structures of palladium-modified copper-zinc oxides ex hydroxycarbonate precursors[J].Chemistry of Materials,2002(4):1863-1872.
[16]	Chusuei C C;Brookshier M A;Goodman D W .Correlation of relative X-ray photoelectron spectroscopy shake-up intensity with CuO particle size[J].LANGMUIR,1999,15(08):2806.
[17]	Chary K V R;Seela K K;Sagar G V et al.Characterization and reactivity of niobia supported copper oxide catalysts[J].Journal of Physical Chemistry B,2004,108(02):658.
[18]	Liu Z;Amiridis MD;Chen Y .Characterization of CuO supported on tetragonal ZrO2 catalysts for N2O decomposition to N-2[J].The journal of physical chemistry, B. Condensed matter, materials, surfaces, interfaces & biophysical,2005(3):1251-1255.
[19]	Huang T J;Tsai D H .CO oxidation behavior of copper and copper oxides[J].Catalysis Letters,2003,87(3-4):173.

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