[1] Hoffmann MR , Martin ST, Won YC. Environmental application of semiconductor photocatalysis. Chem. Rev. , 1995 , 95 : 69~96[2] Zhang WB , Xiao XM, Fu JM, et al . Use of H2O2 advanced oxidation processes for removal of organic pollutants in water. China Water andWastewater , 2002 , 18 (3) : 89~92 (in Chinese with English abstract)[3] Pontius FW. Complying with the new drinking water quality regulations. J . Am. Water Works Assoc , 1990 , 82 : 2~52[4] De Laat J , Dore M. Degradation of chloroethanes in dilute aqueous solution by H2O2PUV. Wat . Res . ,1994 , 28 : 2507~2519[5] Adams CD , Kazhikannil JJ . Effects of UVPH2O2 preoxidation on the aerobic biodegradability of quaternary amine surfactants. Wat . Res . , 2000 ,34 : 668~672[6] Candal RJ , Zeltner WA , Anderson MA. Effect of pH and applied potential on photocurrent and oxidtion rate of saline solutions of formic acid in aphotoelectrocatalytic reactor. Environ. Sci . Technol . , 2000 , 34 : 3443~3451[7] An TC , Zhang WB , Zhu XH , et al . A novel photoelectrocatalytic reactor and photoelectrocatalytic advanced oxidation of formic acid. ChineseJournal of Catalysis , 2003 , 24 : 338~342 (in Chinese with English abstract)[8] Li XZ, Li FB , Fan CM, et al . Photoelectrocatalytic degradation of humic acid in aqueous solution using a TiPTiO2 mesh photoelectrode in aqueoussolution. Wat . Res . , 2002 , 36 :2215~2224[9] Zhang WB , An TC , Xiao XM, et al . Photochemical degradation performance of quinoline aqueous solution in the presence of hydrogen peroxide.J . Environ. Sci . Heal A , 2003 , 38 : 2599~2611[10] Zhang WB , Xiao XM, An TC , et al . Kinetics , degradation pathway and reaction mechanism of advanced oxidation of 42nitrophenol in water byUVPH2O2 process. J . Chem. Technol . Biotechnol . , 2003 , 78 : 788~794[11] Liao CH , Kang SF , Wu FA. Hydroxyl radical scavenging role of chloride and bicarbonate ions in the H2O2PUV process. Chemosphere , 2001 , 44 :1193~1200[12] Zhang WB , Xiao XM, Fu JM, et al . Degradation of nitrophenol in water by UVPH2O2 process and influencing factors. Research of EnvironmentalSciences , 2001 , 14 : 10~11 ,15 (in Chinese with English abstract)[13] Zhang WB , Xiao XM, Fu JM, et al . Effect of anions in aqueous solution on the degradation of 42nitrophenol by UVPH2O2 process. ChinaEnvironmental Science , 2002 , 22 : 301~304 (in Chinese with English abstract)[14] Martin S , Fritz HF. Photochemical degradation of hydrophilic xenobiotics in the UVPH2O2 process : Influence of nitrate on the degradation rate ofEDTA , 22amino212naphthalene2sulfonate , diphenyl242sulfonate and 4 ,4p2diaminostilbene22 , 2p2disulfonate. Wat . Res . , 1997 , 31 : 2885~2891[15] Nadtochenko V , Kiwi J . Primary photochemical reactions in the photo2Fenton system with ferric chloride. 1. A case study of xylidine oxidation asa model compound. Environ. Sci . Technol . , 1998 , 32 : 3273~3281[16] Zhang WB , An TC , Xiao XM, et al . Photoelectrocatalytic degradation of reactive brilliant orange K2R in a new continuous flowphotoelectrocatalytic reactor. Appl . Catal . A , 2003 , 255 : 221~229[17] An TC , Zhang WB , Xiao XM, et al . Photoelectrocatalytic degradation of quinoline with a novel three2dimensional electrode2packed bedphotocatalytic reactor. J . Photochem. Photobio. A , 2004 , 61 : 233~242[18] An TC , Xiong Y, Li GY, et al . Synergetic effect in degradation of formic acid using a new photoelectrochemical reactor. J . Photochem.Photobiol . A , 2002 , 152 : 155~165附中文参考文献[2] 张文兵,肖贤明,傅家谟,等. 过氧化氢高级氧化技术去除水中有机污染物. 中国给水排水, 2002 , 18 (3) :89~92[7] 安太成,张文兵,朱锡海,等. 一种新型光电催化反应器的研制及其对甲酸的光电深度氧化, 催化学报, 2003 , 24 : 338~342[12] 张文兵,肖贤明,傅家谟,等. UVPH2O2 降解水中硝基酚及影响因素. 环境科学研究, 2001 , 14 : 10~11 ,15[13] 张文兵,肖贤明,傅家谟,等. 溶液中阴离子对UVPH2O2 降解42硝基酚的影响. 中国环境科学, 2002 , 22 : 301~304 |