Browse > Article
http://dx.doi.org/10.17820/eri.2016.3.4.256

Application of Ozone Microbubbles in the Field of Water and Wastewater Treatment  

Nam, Gwiwoong (Department of Environmental Science and Ecological Engineering, Korea University)
Jung, Jinho (Department of Environmental Science and Ecological Engineering, Korea University)
Publication Information
Ecology and Resilient Infrastructure / v.3, no.4, 2016 , pp. 256-262 More about this Journal
Abstract
Rapid industrialization and a significant population growth has led to an increased use of chemicals, which has limited the biological processes that account for most of the existing water and wastewater treatment methods. Ozone microbubble technology, which is one of advanced oxidation processes, has recently attracted attention as a method to solve these issues. In this paper, we reviewed both the physical and the chemical characteristics of microbubbles, and evaluated microbubble-based ozone oxidation processes focusing on the removal of various toxic contaminants. In addition, we discussed the potential of an ozone microbubble process as water and wastewater treatment processes by combining it with other treatment technologies.
Keywords
AOP; Microbubble; Ozone; Wastewater; Water;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
연도 인용수 순위
1 Lucas, M.S., Peres, J.A. and Puma, G.L. 2010. Treatment of winery wastewater by ozone-based advanced oxidation processes ($O_3$, $O_3/UV$ and $O_3/UV/H_2O_2$) in a pilot-scale bubble column reactor and process economics. Separation and Purification Technology 72(3): 235-241.   DOI
2 Mestankova, H., Parker, A.M., Bramaz, N., Canonica, S., Schirmer, K., von Gunten, U. and Linden, K.G. 2016. Transformation of contaminant candidate list (CCL3) compounds during ozonation and advanced oxidation processes in drinking water: assessment of biological effects. Water Research 93: 110-120.   DOI
3 Osbeck, S., Bradley, R.H., Liu, C., Idriss, H. and Ward, S. 2011. Effect of an ultraviolet/ozone treatment on the surface texture and functional groups on polyacrylonitrile carbon fibres. Carbon 49(13): 4322-4330.   DOI
4 Suty, H., De Traversay, C. and Cost, M. 2004. Applications of advanced oxidation processes: present and future. Water Science and Technology 49(4): 227-233.
5 Takahashi, M. 2005. $\zeta$ potential of microbubbles in aqueous solutions: electrical properties of the gas-water interface. The Journal of Physical Chemistry B 109(46): 21858-21864.   DOI
6 Takahashi, M., Chiba, K. and Li, P. 2007. Free-radical generation from collapsing microbubbles in the absence of a dynamic stimulus. The Journal of Physical Chemistry B 111(6): 1343-1347.   DOI
7 Tambosi, J.L., De Sena, R.F., Gebhardt, W., Moreira, R.F.P.M., Jose, H.J. and Schroder, H.F. 2009. Physicochemical and advanced oxidation processes-a comparison of elimination results of antibiotic compounds following an MBR treatment. Ozone: Science & Engineering 31(6): 428-435.   DOI
8 Khadhraoui, M., Trabelsi, H., Ksibi, M., Bouguerra, S. and Elleuch, B. 2009. Discoloration and detoxicification of a Congo red dye solution by means of ozone treatment for a possible water reuse. Journal of Hazardous Materials 161(2): 974-981.   DOI
9 Khuntia, S., Majumder, S.K. and Ghosh, P. 2012. Removal of ammonia from water by ozone microbubbles. Industrial & Engineering Chemistry Research 52(1): 318-326.   DOI
10 Khuntia, S., Majumder, S.K. and Ghosh, P. 2015. A pilot plant study of the degradation of Brilliant Green dye using ozone microbubbles: mechanism and kinetics of reaction. Environmental Technology 36(3): 336-347.   DOI
11 Khuntia, S., Majumder, S.K. and Ghosh, P. 2016. Catalytic ozonation of dye in a microbubble system: hydroxyl radical contribution and effect of salt. Journal of Environmental Chemical Engineering 4(2): 2250-2258.   DOI
12 Kim, C.S., Yu, S.Y., Lee, G.I., Kim, S.H., Lee, J.W. and Song, J.K. 2014. Sterilizing effect of plant pathogenic fungi using ozone microbubble. Protected Horticulture and Plant Factory 23(3): 250-255. (in Korean)   DOI
13 Lee, I., Lee, E., Lee, H. and Lee, K. 2011. Removal of COD and color from anaerobic digestion effluent of livestock wastewater by advanced oxidation using microbubbled ozone. Applied Chemistry for Engineering 22(6): 617-622.
14 Lopez-Lopez, A., Pic, J.S. and Debellefontaine, H. 2007. Ozonation of azo dye in a semi-batch reactor: a determination of the molecular and radical contributions. Chemosphere 66(11): 2120-2126.   DOI
15 Agarwal, A., Ng, W.J. and Liu, Y. 2011. Principle and applications of microbubble and nanobubble technology for water treatment. Chemosphere 84(9): 1175-1180.   DOI
16 Chu, L.B., Xing, X.H., Yu, A.F., Sun, X.L. and Jurcik, B. 2008. Enhanced treatment of practical textile wastewater by microbubble ozonation. Process Safety and Environmental Protection 86(5): 389-393.   DOI
17 Ali, U., Syed, J.H., Malik, R.N., Katsoyiannis, A., Li, J., Zhang, G. and Jones, K.C. 2014. Organochlorine pesticides (OCPs) in South Asian region: a review. Science of the Total Environment 476: 705-717.
18 Arslan, I. and Balcioglu, I.A. 2001. Advanced oxidation of raw and biotreated textile industry wastewater with $O_3$, $H_2O_2/UV-C$ and their sequential application. Journal of Chemical Technology and Biotechnology 76(1): 53-60.   DOI
19 Camel, V. and Bermond, A. 1998. The use of ozone and associated oxidation processes in drinking water treatment. Water Research 32(11): 3208-3222.   DOI
20 Chu, L.B., Xing, X.H., Yu, A.F., Zhou, Y.N., Sun, X.L. and Jurcik, B. 2007. Enhanced ozonation of simulated dyestuff wastewater by microbubbles. Chemosphere 68(10): 18541860.   DOI
21 Corona-Vasquez, B., Samuelson, A., Rennecker, J.L. and Marinas, B.J. 2002. Inactivation of Cryptosporidium parvum oocysts with ozone and free chlorine. Water Research 36(16): 4053-4063.   DOI
22 Facile, N., Barbeau, B., Prevost, M. and Koudjonou, B. 2000. Evaluating bacterial aerobic spores as a surrogate for Giardia and Cryptosporidium inactivation by ozone. Water Research 34(12): 3238-3246.   DOI
23 Ghosh, P. 2009. Colloid and Interface Science. PHI Learning Private. Ltd, New Delhi, India.
24 Kerfoot, W.B. and LeCheminant, P. 2003. Ozone microbubble sparging at a California site. In, Moyer, E.E. and Kostecki, P.T. (eds.), MTBE Remediation Handbook. Springer, Amherst, Massachusetts, USA. pp. 455-472.
25 Gracia, R., Aragues, J. L. and Ovelleiro, J.L. 1996. Study of the catalytic ozonation of humic substances in water and their ozonation byproducts. Ozone: Science & Engineering 18(3): 195-208.   DOI
26 Ikeura, H., Kobayashi, F. and Tamaki, M. 2011. Removal of residual pesticide, fenitrothion, in vegetables by using ozone microbubbles generated by different methods. Journal of Food Engineering 103(3): 345-349.   DOI
27 Jabesa, A. and Ghosh, P. 2016a. Removal of dimethyl phthalate from water by ozone microbubbles. Environmental Technology 27: 1-11.
28 Jabesa, A. and Ghosh, P. 2016b. Removal of diethyl phthalate from water by ozone microbubbles in a pilot plant. Journal of Environmental Management 180: 476-484.   DOI
29 Kerfoot, W.B. and McGrath, A. 2001. Microbubble oxidation smokes MTBE and BTEX. Contaminated Soil Sediment and Water Spring (Special Issue): 77-78.
30 Kerfoot, W.B., Ehleringer, B. and Muncy, J. 2008. Ozone sparging closure of an industrial VOC spill site adjacent to a water supply well site. Ozone: Science & Engineering 30(1): 88-92.   DOI
31 Vandevivere, P.C., Bianchi, R. and Verstraete, W. 1998. Review: treatment and reuse of wastewater from the textile wet-processing industry: review of emerging technologies. Journal of Chemical Technology and Biotechnology 72(4): 289-302.   DOI
32 Walker, A.B., Tsouris, C., DePaoli, D.W. and Thomas Klasson, K. 2001. Ozonation of soluble organics in aqueous solutions using microbubbles. Ozone: Science & Engineering 23(1): 77-87.   DOI
33 Zhang, F., Xi, J., Huang, J.J. and Hu, H.Y. 2013. Effect of inlet ozone concentration on the performance of a micro-bubble ozonation system for inactivation of Bacillus subtilis spores. Separation and Purification Technology 114: 126-133.   DOI
34 Wang, C., Yediler, A., Lienert, D., Wang, Z. and Kettrup, A. 2003. Ozonation of an azo dye CI Remazol Black 5 and toxicological assessment of its oxidation products. Chemosphere 52(7): 1225-1232.   DOI
35 Wu, C.H., Kuo, C.Y. and Chang, C.L. 2008. Homogeneous catalytic ozonation of CI Reactive Red 2 by metallic ions in a bubble column reactor. Journal of Hazardous Materials 154(1): 748-755.   DOI
36 Xia, Z. and Hu, L. 2016. Remediation of organics contaminated groundwater by ozone micro-nano bubble. Japanese Geotechnical Society Special Publication 2(57): 1978-1981.   DOI
37 Xu, P., Janex, M.L., Savoye, P., Cockx, A. and Lazarova, V. 2002. Wastewater disinfection by ozone: main parameters for process design. Water Research 36(4): 1043-1055.   DOI
38 Xu, Z., Mochida, K., Naito, T. and Yasuda, K. 2012. Effects of operational conditions on 1, 4-dioxane degradation by combined use of ultrasound and ozone microbubbles. Japanese Journal of Applied Physics 51(7S): 07GD08.   DOI
39 Zheng, T., Wang, Q., Zhang, T., Shi, Z., Tian, Y., Shi, S., Smale, N. and Wang, J. 2015a. Microbubble enhanced ozonation process for advanced treatment of wastewater produced in acrylic fiber manufacturing industry. Journal of Hazardous Materials 287: 412-420.   DOI
40 Zheng, T., Zhang, T., Wang, Q., Tian, Y., Shi, Z., Smale, N. and Xu, B. 2015b. Advanced treatment of acrylic fiber manufacturing wastewater with a combined microbubble-ozonation/ultraviolet irradiation process. RSC Advances 5(95): 77601-77609.   DOI
41 Zhu, X.F. and Xu, X.H. 2004. The mechanism of Fe (III)-catalyzed ozonation of phenol. Journal of Zhejiang University Science 5(12): 1543-1547.   DOI