Advanced Oxidation Wastewater Treatment

Gogate, PR Pandit, AB. A review of imperative technologies for wastewater treatment 1 oxidation technologies at ambient conditions. Advances in Environmental Research, 2004 8, 501-551. 

Parsons, S. (2004) Advanced Oxidation Processes for Water and Wastewater Treatment, IWA Publishing, London. 

Membrane separators, 23 795-796 Membrane/sonication/wet oxidation (MEMSONIWO) systems in wastewater treatment, 25 911-912 Membrane systems, as advanced wastewater treatment, 25 909 Membrane technology, 25 796-852 applications for, 25 824-848 in controlled drug delivery,... 

The advanced oxidation processes offer the possibility for destruction of recalcitrant biodegradable and toxic organic pollutants. The field of applications regarding wastewater treatment varies. AOPs can be applied as ... 

Advanced wastewater treatment techniques, for example oxidation processes, can achieve up to 100% removal for diclofenac [52,53], Reverse osmosis, activated carbon and ozonation have been shown to significantly reduce or eliminate antibiotics from wastewater effluents [32], The efficiency of two tertiary treatments, chlorination and UV disinfection, was compared and chlorination led to lower quantities of antibiotics [54],... 

Parsons, SA Williams, M. Introduction. In Parsons SA, editor. Advanced oxidation processes for water and wastewater treatment. London IWA Publishing 2004 1-6. 

Rodriguez, M. Fenton and UV-VIS based advanced oxidation processes in wastewater treatment Degradation, mineralization and biodegradability enhancement. PhD Thesis. Barcelona University of Barcelona, 2003. 

Bigot V, Luck F, Paillard H, Wagner A (1994) Evaluation of advanced oxidation processes for landfill leachate treatment, in Proceedings of the international ozone symposium Application of ozone in water and wastewater treatment , Bln A K (ed.) Warsaw Poland May 26-27 330-343. 

Masten S J, Galbraith MJ, Davies S HR (1993) Oxidation of Trichlorobenzene Using Advanced Oxidation Processes, Ozone in Water and Wastewater Treatment, 1 llh Ozone World Congress, 20/45-20/49. 

LaplancheA, Orta de Velasquez M T, Boisdon V, Martin N, Martin G (1993) Modelisation of Micropollutant Removal in Drinking water Treatment by Ozonation or Advanced Oxidation Processes (03/H202), Ozone in Water and Wastewater Treatment-Proceedings of the 11th Ozone World Congress San Francisco, 17-90. 

Preis, S., Kamenev, S., Kallas, J., and Munter, R., Advance oxidation process against phenolic compounds in wastewater treatment, Ozone Sci. Eng., 17, 399-418, 1995. 

O3/UV/H2O2 AOTs, together with other processes treated in different chapters (such as Fenton oxidation), can be named ambient (temperature and pressure), advanced oxidation technologies, in contrast with other AOTs such as hydrothermal oxidation processes that require pressures and temperatures above 1 MPa and 150°C, respectively, and which are more suitable for the treatment of concentrated wastewaters. It is evident that appropriate ranges of concentrations for the different oxidation technologies cannot be exactly established but some recommended values have been reported [29]. Fig. 1 shows some possible recommended ranges of concentrations for these types of AOTs. 

As can be observed from Table 12, these studies on the application of advanced oxidations cover a wide range of uses, including degradation of pollutants [197,210,211,213,217-220], disinfection [197,215], maintenance of swimming-pools [216], and treatment of cooling waters [214], leachates [221], and domestic wastewater [222]. 

Preis S, Kamenev S, Kallas J, Munter R. Advanced oxidation processes against phenolic compounds in wastewater treatment plant. Ozone Sci Eng 1995 17 399-418. 

Comninellis, Ch. and Pulgarin, C. (1993) Electrochemical oxidation of phenol for wastewater treatment using Sn02 anodes. I. Appl. Electrochem. 23, 108-112 Faouzi, M., Cafiizares, R, Gadri, A., Lobato, I., Nasr, B., Paz, R., Rodrigo, M.A. and Saez, C. (2006) Advanced oxidation processes for the treatment of wastes polluted with azoic dyes. Electrochim. Acta 52, 325-331... 

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