中文
Earlier issues
Announcement
More
Progress in Chemistry 2008, Vol. 20 Issue (0708): 1187-1195 Previous Articles   Next Articles

• Review •

Treatment of Organic Pollutants in Water by Ultrasound

Li Mei1,2 Li Jitai1** Sun Hanwen1   

  1. (1.College of Chemistry and Environmental Science, Hebei University, Key Laboratory of Analytical Science and Technology of Hebei Province, Baoding 071002, China
    2. College of Chemistry and Material Science, Hebei Normal University, ShiJiazhuang, 050016, China)
  • Received: Revised: Online: Published:
  • Contact: Li Jitai
PDF ( 2018 ) Cited
Export

EndNote

Ris

BibTeX

In recent years, increasing attention has been focused on the application of ultrasound for the destruction of organic contaminations in water. Compared with conventional treatment methods, the ultrasonic treatment increases the degradation efficiency and reduces the time required for removing the organic contaminations. Ultrasonic technology has been proven to be effective for the degradation of the most refractory organic pollutants. The principle and the major influencing factors on degradation efficiency and methods (including ultrasound irradiation individually and ultrasonic waves in conjunction with other techniques such as bio-catalyst, chemical oxidation, and adsorption) of ultrasonic degradation are described in this paper. Progress in treatment of organic pollutants in water by using ultrasound technology is reviewed. Moreover, existing problems and future study directions are discussed.
Key words: ultrasound, cavitations, organic pollutants, degradation

CLC Number: 

[ 1 ] David B , Lhote M, Faure V , et al . Wat . Res. , 1998 , 32 (8) :2451 —2461
[ 2 ] Ayyildiz O , Anderson P R , Peters R W. Journal of Hazardous Materials , 2005 , B120 : 149 —156
[ 3 ] Peters D. Ultrason. Sonochem. , 2001 , 8 : 221 —226
[ 4 ] Ku Y, Tu Y H , Ma C M. Wat . Res. , 2005 , 39 : 1093 —1098
[ 5 ] Mason T J . Practical Sonochemistry. New York : Ellis Horwood ,1991. 17 —21
[ 6 ] Rae J , Ashokkumar M, Eulaerts O , et al . Ultrason. Sonochem. ,2005 , 12 : 325 —329
[ 7 ] Hoffmann M R , Hua I , Hêchemer R. Ultrason. Sonochem. ,1996 , 3 : S163 —S172
[ 8 ] 张卫华(Zhang W H) , 全燮(Quan X) , 陈硕(Cheng S) , 张卓勇(Zhang Z Y) . 化学通报(Chemistry) , 2005 , 68(1) : 1 —8
[ 9 ] Drijvers D , Baets R D , Visscher A D , et al . Ultrason.Sonochem. , 1996 , 3 : S83 —S90
[10] Selli E , Bianchi C L , Pirola C , et al . Ultrason. Sonochem. ,2005 , 12 : 395 —400
[11] Rehorek A , Hoffmann P , Kandelbauer A , et al . Chemosphere ,2007 , 67 : 1526 —1532
[12] 宋勇( Song Y) , 戴友芝(Dai Y Z) . 工业安全与环保( Industrial Safety and Environmental Protection) , 2005 , 31 (7) :1 —3
[13] 马军(Ma J ) , 赵雷( Zhao L) . 黑龙江大学自然科学学报(Journal of Natural Science of Heilongjiang University) , 2005 , 22(2) : 141 —147
[14] 肖小明(Xiao X M) , 李洪青(Li H Q) , 邹华生(Zou H S) . 环境科学与技术(Environmental Science and Technology) , 2003 ,26 (增刊) : 84 —86
[15] 谢家声(Xie J S) , 肖士民(Xiao S M) , 曹人平(Cao R P) . 四川环境(Sichuan Environment) , 2005 , 24 (2) : 35 —38
[16] Entezari M H , Kruus P , Otson R. Ultrason. Sonochem. , 1997 ,4 : 49 —54
[17] Guo Z B , Zheng Z , Zheng S R , et al . Ultrason. Sonochem. ,2005 , 12 : 461 —465
[18] Sivakumar M, Pandit A B. Ultrason. Sonochem. , 2001 , 8 :233 —240
[19] Nagata Y, Nakagawa M, Okuno H , et al . Ultrason. Sonochem. ,2000 , 7 : 115 —120
[20] Kojima Y, Fujita T , Ona E P , et al . Ultrason. Sonochem. ,2005 , 12 : 359 —365
[21] Okitsu K, Iwasaki K, Yobiko Y, et al . Ultrason. Sonochem. ,2005 , 12 : 255 —262
[22] Wang J , Guo B D , Zhang X D , et al . Ultrason. Sonochem. ,2005 , 12 : 331 —337
[23] Zheng W X, Maurin M, Tarr MA. Ultrason. Sonochem. , 2005 ,12 : 313 —317
[24] Minero C , Pellizzari P , Maurino V , et al . Applied Catalysis B :Environmental , 2007 , 77 : 308 —316
[25] Shimizu N , Ogino C , Dadjour M F , Murata T. Ultrason.Sonochem. , 2007 , 14 : 184 —190
[26] Okuno H , Yim B , Mizukoshi Y, et al . Ultrason. Sonochem. ,2000 , 7 : 261 —264
[27] Shemer H , Narkis N. Ultrason. Sonochem. , 2005 , 12 :495 —499
[28] 沈壮志(Shen Z Z) , 程建政(Cheng J Z) , 吴胜举(Wu S J ) .化学学报(Acta Chimica Sinica) , 2003 , 61(12) : 2016 —2019
[29] 赵德明(Zhao D M) , 史惠祥(Shi H X) , 雷乐成(Lei L C) , 汪大 (Wang D H) . 浙江大学学报( 工学版) (Journal of Zhejiang University) (Engineering Science) , 2004 , 1 : 114 —120
[30] Zhang H , Duan L J , Zhang D B. Journal of Hazardous Materials ,2006 , B138 : 53 —59
[31] Kubo M, Matsuoka K, Takahashi A , et al . Ultrason.Sonochem. , 2005 , 12 : 263 —269
[32] Lin J G, Chang C N , Wu J R. Wat . Sci . Tech. , 1996 , 33(6) :75 —81
[33] Lin J G, Chang C N , Wu J R , et al . Wat . Sci . Tech. , 1996 ,34 (9) : 41 —48
[34] Chemat F , Teunissen P G M, Chemat S , et al . Ultrason.Sonochem. , 2001 , 8 : 247 —250
[35] Neppolian B , Jung H , Choi H , Lee J H , Kang J W. Wat . Res. ,2002 , 36 : 4699 —4708
[36] Visscher A D , Langenhove H V. Ultrason. Sonochem. , 1998 , 5 :87 —92
[37] Adewuyi Y G. Environ. Sci . Technol . , 2005 , 39 : 3409 —3420
[38] Adewuyi Y G. Environ. Sci . Technol . , 2005 , 39 : 8557 —8570
[39] Blume T , Neis U. Ultrason. Sonochem. , 2004 , 11 : 333 —336
[40] Sangave P C , Pandit A B. Ultrason. Sonochem. , 2004 , 11 :197 —203
[41] Hirano K, Nitta H , Sawadw K. Ultrason. Sonochem. , 2005 , 12 :271 —276
[42] Entezari M H , Pétrier C. Ultrason. Sonochem. , 2005 , 12 :283 —288
[43] Entezari M H , Mostafai M, Sarafraz-Yazdi A. Ultrason.Sonochem. , 2006 , 13 : 37 —41
[44] Bernardo E C , Fukuta T , Fujita T , Ona E P. Ultrason.Sonochem. , 2006 , 13 : 13 —18
[45] Iida Y, Kozuka T , Tuziut T , et al . Ultrasonics , 2004 , 42 :635 —639
[46] 王三反( Wang S F ) . 中国给排水( China Water and Wastewater) , 1998 , 14 (2) : 24 —26
[47] Breitbach M, Bathen D. Ultrason. Sonochem. , 2001 , 8 :277 —283
[48] Ge J T , Qu J H. Applied Catalysis B : Environmental , 2004 , 47 :133 —140
[49] Dai Y Z , Li F F , Ge F , et al . Journal of Hazardous Materials ,2006 , B137 : 1424 —1429
[50] Li J T , Li M, Li J H , et al . Ultrason. Sonochem. , 2007 , 14 :62 —66
[51] Li J T , Li M, Li J H , et al . Ultrason. Sonochem. , 2007 , 14 :241 —245
[52] Rehorek A , Tauber M, Gübitz G. Ultrason. Sonochem. , 2004 ,11 : 177 —182
[53] Mrowetz M, Pirola C , Selli E. Ultrason. Sonochem. , 2003 , 10 :247 —254
[54] Guyer T G, Ince N H. Ultrasonics , 2004 , 42 : 603 —609
[55] 葛建团(Ge J T) , 曲久辉(Qu J H) , 徐敏(Xu M) . 环境科学(Environmental Science) , 2004 , 25(4) : 90 —93
[56] Guyer G T , Ince N H. Ultrason. Sonochem. , 2003 , 10 :235 —240
[57] Ince N H , Güyer G T. Ultrasonics , 2004 , 42 : 591 —596
[58] Velegraki T , Poulis I , Charalabaki M, et al . Applied Catalysis B :Environmental , 2006 , 62 : 159 —168
[59] He Z Q , Song S , Xia M, et al . Chemosphere , 2007 , 69 :191 —199
[60] Berberidou C , Poulios I , Xekoukoulotakis N P , et al . Applied Catalysis B : Environmental , 2007 , 74 : 63 —72
[61] Hao H W, Chen Y F , Wu M S , et al . Ultrason. Sonochem. ,2004 , 11 : 43 —46
[62] Kidak R , Ince N H. Journal of Hazardous Materials , 2007 , 146 :630 —635
[63] Pandit A B , Gogate P R , Mujumder S. Ultrason. Sonochem. ,2001 , 8 : 227 —231
[64] Tauber A , Schuchmann H P , Sonntag C V. Ultrason.Sonochem. , 2000 , 7 : 45 —52
[65] Entezari M H , Pétrier C , Devidal P. Ultrason. Sonochem. ,2003 , 10 : 103 —108
[66] Torres R A , Abdelmalek F , Combet E , et al . Journal of Hazardous Materials , 2007 , 146 : 546 —551
[67] Liang J , Komarov S , Hayashi N , Kasai E. Ultrason. Sonochem. ,2007 , 14 : 201 —207
[68] Taghizadeh M T , Mehrdad A. Ultrason. Sonochem. , 2003 , 10 :309 —313
[69] Li Y T , Li J , Guo S Y, et al . Ultrason. Sonochem. , 2005 , 12 :183 —189
[70] Taylor E Jr , Cook B B , Tarr M A. Ultrason. Sonochem. , 1999 ,6 : 175 —183
[71] Wheat P E , Tumeo M A. Ultrason. Sonochem. , 1997 , 4 :55 —59
[72] Psillakis E , Goula G, Kalogerakis N , et al . Journal of Hazardous Materials , 2004 , B108 : 95 —102
[73] 傅敏(Fu M) , 丁培道(Ding P D) , 蒋永生(Jiang Y S) , 高宇(Gao Y) . 重庆环境科学(Chongqing Environmental Sciences) ,2003 , 25(12) : 27 —29
[74] 孙红杰( Sun H J ) , 张志群( Zhang Z Q) . 中国环境科学(China Environmental Science) , 2002 , 22(3) : 210 —213
[75] Bianchi C L , Pirola C , Ragaini V , et al . Applied Catalysis B :Environmental , 2006 , 64 : 131 —138
[76] Wang J , Ma T , Zhang Z H , et al . Journal of Hazardous Materials , 2006 , B137 : 972 —980
[77] Hartmann J , Bartels P , Mau U , et al . Chemosphere , 2008 , 70(3) : 453 —461
[78] Nakui H , Okitsu K, Maeda Y, et al . Journal of Hazardous Materials , 2007 , 146 : 636 —639
[79] Song W H , O'Shea K E. Wat . Res. , 2007 , 41 : 2672 —2678
[80] Katsumata H , Kaneco S , Suzuki T , et al . Chemosphere , 2007 ,69 : 1261 —1266
[81] Song S , Xia M, He Z Q , et al . Journal of Hazardous Materials ,2007 , 144 : 532 —537
[1] Lan Mingyan, Zhang Xiuwu, Chu Hongyu, Wang Chongchen. MIL-101(Fe) and Its Composites for Catalytic Removal of Pollutants: Synthesis Strategies, Performances and Mechanisms [J]. Progress in Chemistry, 2023, 35(3): 458-474.
[2] Li Zhou, Abdelkrim Yasmine, Zhiguo Jiang, Zhongzhen Yu, Jin Qu. Microplastics: A Review on Biological Effects, Analysis and Degradation Methods [J]. Progress in Chemistry, 2022, 34(9): 1935-1946.
[3] Qianqian Fan, Lu Wen, Jianzhong Ma. Lead-Free Halide Perovskite Nanocrystals: A New Generation of Photocatalytic Materials [J]. Progress in Chemistry, 2022, 34(8): 1809-1814.
[4] Xin Pang, Shixiang Xue, Tong Zhou, Hudie Yuan, Chong Liu, Wanying Lei. Advances in Two-Dimensional Black Phosphorus-Based Nanostructures for Photocatalytic Applications [J]. Progress in Chemistry, 2022, 34(3): 630-642.
[5] Nan Wang, Yuqi Zhou, Ziye Jiang, Tianyu Lv, Jin Lin, Zhou Song, Lihua Zhu. Synergistically Consecutive Reduction and Oxidation of Per- and Poly-Halogenated Organic Pollutants [J]. Progress in Chemistry, 2022, 34(12): 2667-2685.
[6] Xiaoping Chen, Qiaoshan Chen, Jinhong Bi. Photocatalytic Degradation of Polycyclic Aromatic Hydrocarbon in Soil [J]. Progress in Chemistry, 2021, 33(8): 1323-1330.
[7] Wenliang Han, Linyang Dong. Activation Methods of Advanced Oxidation Processes Based on Sulfate Radical and Their Applications in The Degradation of Organic Pollutants [J]. Progress in Chemistry, 2021, 33(8): 1426-1439.
[8] Xiaohong Yi, Chongchen Wang. Elimination of Emerging Organic Contaminants in Wastewater by Advanced Oxidation Process Over Iron-Based MOFs and Their Composites [J]. Progress in Chemistry, 2021, 33(3): 471-489.
[9] Hongfei Bi, Jinsong Liu, Zhengying Wu, He Suo, Xueliang Lv, Yunlong Fu. Modified Synthesis and Photocatalytic Properties of Indium Zinc Sulfide [J]. Progress in Chemistry, 2021, 33(12): 2334-2347.
[10] Yong Feng, Yu Li, Guangguo Ying. Micro-Interface Electron Transfer Oxidation Based on Persulfate Activation [J]. Progress in Chemistry, 2021, 33(11): 2138-2149.
[11] Lin Gu, Kai Zhang, Haixiang Yu, Guangxia Dong, Xingbo Qiao, Haifeng Wen. Synthesis of Sludge Carbon-Based Catalytic Materials and Their Application in Water Environment [J]. Progress in Chemistry, 2020, 32(9): 1412-1426.
[12] Zhengying Wu, Xie Liu, Jinsong Liu, Shouqing Liu, Zhenlong Zha, Zhigang Chen. Molybdenum Disulfide Based Composites and Their Photocatalytic Degradation and Hydrogen Evolution Properties [J]. Progress in Chemistry, 2019, 31(8): 1086-1102.
[13] Yue Liu, Yihan Wu, Hongwei Pang, Xiangxue Wang, Shujun Yu, Xiangke Wang. Study on the Removal of Water Pollutants by Graphite Phase Carbon Nitride Materials [J]. Progress in Chemistry, 2019, 31(6): 831-846.
[14] Yuekun Ye, Bin Chi, Shijie Jiang, Shijun Liao. Enhancing the Durability of Membrane Electrode Assembly of Proton Exchange Membrane Fuel Cells [J]. Progress in Chemistry, 2019, 31(12): 1637-1652.
[15] Junjian An, Mengling Wang, Mengxuan Huang, Peng Wang, Guangyan Zhang. Environmental Catalytic Performance of BiFeO3 and Its Modifier [J]. Progress in Chemistry, 2018, 30(9): 1298-1307.