磁场作用下的苯酚光催化氧化反应研究
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摘要
本文研究了磁场作用对光助Fenton试剂氧化降解苯酚反应的影响和在TiO_2催化剂上的苯酚溶液光催化氧化反应。在Photo-Fenton反应体系中引入磁场作用改变了苯酚溶液光催化氧化的反应进程。在空气流量为400ml/min,苯酚水溶液通过磁场的流速为100mm/s,预磁化时间为5min时,获得最佳磁化效果:苯酚去除率增加了10%,COD去除率增加了7%。此条件下未测到磁化作用对TOC去除率的影响。通过动力学分析表明,磁场作用提高了反应速率常数。
在TiO_2催化剂上的苯酚溶液光催化氧化反应中,着重研究了热处理过程中的温度和气氛对以钛酸四丁酯为原料,采用水解过程制备的TiO_2在各种光源下的光催化活性。主要考察了催化剂在紫外光、日光灯、太阳光下的光催化活性,发现在催化剂中引入碳、氮等元素可提高催化剂在可见光范围内的光催化活性。在太阳光照射下,反应90min后100ppm苯酚转化率达到了25%。
The effect of magnetic field on the oxidation of phenol solution with UV/Fenton reagent and Photo-catalytic degradation of phenol by using titanium dioxide were investigated. The enhancement of 10% phenol conversion and 7% COD removal was achieved after 5min magnetization before UV irradiation, at 400ml/min air flow, 100mm/s liquid flow rate through the magnetic field. Effect of magnetic field on TOC removal was not detected under current test condition. Through kinetic analysis, it is shown that magnetic field effect increased the reaction constant.
Photo-catalytic degradation of phenol solution by using titanium dioxide prepared with hydrolysis Tetra-n-butly titanate was studied with different kinds of light sources. The photo-catalytic activities of the prepared samples were evaluated by measuring the phenol conversion. Results indicated that the solar is more applicable for photo-catalytic reaction than fluorescence. The 25% phenol conversion was achieved after 90min of reaction time. Analyzing the mechanism of photons attaching the catalyst particles and spectrum of the light sources, it could be confirmed that a mount N and C doped can greatly enhance light adsorption range of titanium dioxide, which make it possible that degrades organic under solar ray.
在TiO_2催化剂上的苯酚溶液光催化氧化反应中,着重研究了热处理过程中的温度和气氛对以钛酸四丁酯为原料,采用水解过程制备的TiO_2在各种光源下的光催化活性。主要考察了催化剂在紫外光、日光灯、太阳光下的光催化活性,发现在催化剂中引入碳、氮等元素可提高催化剂在可见光范围内的光催化活性。在太阳光照射下,反应90min后100ppm苯酚转化率达到了25%。
The effect of magnetic field on the oxidation of phenol solution with UV/Fenton reagent and Photo-catalytic degradation of phenol by using titanium dioxide were investigated. The enhancement of 10% phenol conversion and 7% COD removal was achieved after 5min magnetization before UV irradiation, at 400ml/min air flow, 100mm/s liquid flow rate through the magnetic field. Effect of magnetic field on TOC removal was not detected under current test condition. Through kinetic analysis, it is shown that magnetic field effect increased the reaction constant.
Photo-catalytic degradation of phenol solution by using titanium dioxide prepared with hydrolysis Tetra-n-butly titanate was studied with different kinds of light sources. The photo-catalytic activities of the prepared samples were evaluated by measuring the phenol conversion. Results indicated that the solar is more applicable for photo-catalytic reaction than fluorescence. The 25% phenol conversion was achieved after 90min of reaction time. Analyzing the mechanism of photons attaching the catalyst particles and spectrum of the light sources, it could be confirmed that a mount N and C doped can greatly enhance light adsorption range of titanium dioxide, which make it possible that degrades organic under solar ray.
引文
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and their use as photocatalysts, Materials Research Bulletin, 2001, 36
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[47] 崔鹏,魏风玉,二氧化钛负载型光催化剂的制备与降解性能研究,合肥工业大学学报,自然科学版,2001,24(5)994-997
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[2] Bossmann. S.H, Oliveros E, GbSetal. New evidence against hydroxyl radicals as reactive intermediates in the thermal and photo-chemically enhanced Fenton Reaction. J. Phys. Chem. A, 1998, 102(28),
[3] Huston. P.L and Pignatello. J Reduction of per-chloroalkanes by ferrioxalate-generated carboxylat radical preceding mineralization by the photo-Fenton reation. Environ. Sci. Technol. 1996, 30(12)
[4] 徐新华,邻氯苯酚废水的光助Fenton-生化法处理研究,浙江大学博士学位论文
[5] 李太友.光助Fenton法氧化降解苯胺的研究,江汉大学学报,2001,18(6)13-17
[6] 陈传好,Fenton试剂处理废水中各影响因子的作用机制,环境科学,2000,5,93-96
[7] 安立超,利用芬顿试剂处理硝基苯类生产废水的研究,环境科学与技术2001,12(24)3-4
[8] Soo-M. Kim, sven-U. Geissen and Alfons Vogelphol. Landfill Leachate Treatment by a photo-assistented Fenton Reaction. Wat. Sci. Tech, Vol. 35, No. 4, 1997
[9] 张乃东,UV/Fenton法处理水中苯酚的研究.哈尔滨商业大学学报,2001,17(1)35-38
[10] 陆文明,Fenton试剂处理碱性品红溶液的实验研究,洛阳工业高等专科学校学报,2001,11(1)17-20
[11] 李绍峰,Fenton试剂降解水中活性染料的研究,哈尔滨建筑大学学报,2001,34(5)76-80
[12] G. Ruppert and R. bauser, The Photo-Fenton Reaction-an effective photochemical wastewater treatment process, J. Photochem. Photoboil. A: chem, 73(1993)
[13] 赵进才,Photo-Fenton反应研究进展.感光科学与光化学,2000,18(4)357-365
[14] 樊美公,光化学基本原理与光子学材料科学,科学出版社,2001,17-22
[15] 张立德,纳米材料学[M],沈阳,辽宁科技出版社,1994,9,45-81
[16] 张青红,高濂,四氯化钛水解法制备纳米氧化钛超细粉体[J],无机材料学报,2000,15,21-25
[17] 沈伟韧,超临界干燥法制备TiO_2气凝胶,催化学报,1999,20(3)365-367
[18] 卫志贤,溶胶-凝胶法制纳米二氧化钛小试放大研究,无机盐工业,1998,30(5)
[19] Degan D, TiO_2 Aerogels for Photo-catalytic Decontamination of Acquitic Environments, J. Phys. Chem, 1993, 97 (49) 12651—12655
[20] 陈龙武,气凝胶的制备[J],化学通报,1997,60(8)21-26
[21] 沈伟韧,超临界干燥法制备TiO_2气凝胶,催化学报,1999,20(3)365-367
[22] 张敬畅,超临界流体干燥法制备纳米级TiO_2的研究,无机材料学报,1999,14(1)29-35
[23] 施尔畏.水热法的应用与发展,无机材料学报,1996,11(2)16-19
[24] 赵文宽,高热稳定性锐钛矿型TiO_2纳米粉体的制备,无机材料学报,1998,13(4)608-612
[25] Manjari lar, Preparation of Nanosized TiO_2 by Micro emulsion Method, Mater. Res. 1998. 13(5)
[26] 高濂.醇盐水解法制备二氧化钛纳米粉体,无机材料学报,1995,10(4)
[27] 汪军,纳米二氧化钛的光催化机理及其应用研究,污染防治技术,1998,11(3)
[28] 吴天宝.太阳能TiQ_2非均相催化氧化染料污水脱色研究,中国环境科学,1997,17(1)
[29] Boris Levy, Journal of electro ceramics: photo of nano material for enger application, V13, 1997
[30] Ihara T, Miyoshi M, Ando M, Sugihara S, Iriyama Y. Preparation of a visible-light-active TiO_2 photo-catalyst by RF plasma treatment. Journal of Materials Science vol, 2001, 36(17)
[31] 曾人杰,林仲华,光诱导二氧化钛超亲水薄膜SEP图像分析和氧空位电位浓度理论探讨,电化学,2001,7(4)413-420
[32] 刘鸿,氢处理手段促进TiO_2光催化活性的原因,2002全国光学术会议1021-1025
[33] 刘鸿,氢处理二氧化钛的光催化性能及电化学阻抗谱,物理化学学报,2001,17(3)
[34] 刘鸿,氢还原二氧化钛光催化降解磺基水杨酸的研究,分子催化,2001,15(1)47-50
[35] Juan M Coronado, ESR study of the surface characteristic of nanostructed TiO_2 under Irradiation, Langmuir, 2001, 17
[36] Idriss H, Legare P, Dark and photoreaction of acetates on TiO_2/sub2/(110)single crystal surface, surface Science, vol. 515
[37] Pietron, JJ Rolisonm, D R, Eletron chemically induced surface modification of titanolisn a nanoglue solids, 2001.285(1)
[38] Znaidi L, etal, A semicontinous process for the synthesis of nanosized TiO_2 powders and their use as photocatalysts, Material Research Bulletin, 2001, 36
[39] Deng, zhaong sheng, etal. Prepararion and phtocatalytic activity of TiO_2-SiO_2 binary aerogel, Nanostructed materials, 1999, 11(8)
[40] Yusuf M. Imai H. Preparation of poroustitania film by modified sol-gel method and its application to photocatalyst. Journal of Sol-gel Science & Technology, vol25
[41] Negishi N. Takeuchi K, Ibusuki T. DatyeAk. The microstructure of TiO_2 photocatalyst thin films. Journal of materials science Letter, vol18
[42] 周磊,赵文宽,也相沉积法制备光催化活性TiO_2,2002全国光学术会议1035-1039
[43] Pietron, J Rolisom, D R, Electron chemically induced surface modified of titanolisn a crystalline Solids, 2001, 285
[44] Znaidi L, etal, Asemicontinous process for the synthesis of nanosized TiO_2 powders
and their use as photocatalysts, Materials Research Bulletin, 2001, 36
[45] Wu JCS, Chih-Yang Yeh, Sol-gel-derived photosensitive TiO_2 and Cu/ TiO_2 using homogeneous hydrolysis technique. Journal of materials research, vol 16(2)
[46] Jiaguo Yu. Xiujian Zhao, Effect of substrates on the photocatalytic activity of nanometer TiO_2 thin films. Materials research Bulletin, vol 35(8)
[47] 崔鹏,魏风玉,二氧化钛负载型光催化剂的制备与降解性能研究,合肥工业大学学报,自然科学版,2001,24(5)994-997
[48] 克拉辛(毛钜凡等译),磁化水,北京,计量出版社,1982,165-198
[49] 马伟等,磁场效应在水处理中的作用与研究,工业水处理,1997,17(6)1-3
[50] 曹昌年.进入水处理的物理方法,物理,1993,22(6),22-25
[51] 北京市环境保护科学研究所,水污染防治手册,上海,上海科学技术出版社,1989,350-352
[52] 颜幼平等,高梯度磁分离技术在环境保护中的应用,环境保护科学,1999,25(3)9-11
[53] 周开学等,磁防垢机理研究现状与进展,石油大学学报,1999,23(5)109-113
[54] 王国全等,磁化学与磁医学,北京,兵器工业出版社,1997,98-101
[55] 王平等,有机污水磁处理实验研究,环境科学与技术,1999,(4)22-25
[56] 王祥三等.磁化处理污水的生物效应试验,环境科学与技术,2000(2)33-36
[57] 雷国元.磁种和磁处理技术在废水处理中的应用,上海环境科学,1997,16(11)24-27
[58] 谢绮芬,磁水器的防垢机理及设计,水处理技术,1985,11(2),49
[59] 杨耀宾,蒋勇,温龙等,水处理技术,1992,18(5),335
[60] 张宝铭,刘有昌.水的磁化处理研究,工业水处理,1994,14(3),10
[61] John Donason, Preliminary observations on the control of algal growth by magnetic treatment of water New Scientist, 1988, 18(4): 43
[62] JSvoboda. Internation Journal of Mineral Processing, 1981, 8: 377
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