Library

UNKNOWN (n.y): A woman uses a sari cloth to strain water. Centre for Affordable Water and Sanitation Technology (CAWST). Factsheet: STraining URL [Accessed: 24.05.2019]

Both reverse osmosis and ion exchange technologies are well established and have reached advanced levels of development. Comparison of the two processes for water demineralisation can therefore be reliably made and cost comparisons can be carried out on a case-by-case basis. This document examines the significant factors that should be taken into account in the comparison and gives guidelines for decision making.

PUROLITE INTERNATIONAL (2003): Guidelines for Selecting Resin Ion Exchange or Reverse Osmosis for Feed Water Demineralisation. In: Purolite.com: URL [Accessed: 24.05.2019]

https://www.koshland-science-museum.org/water/html/en/Treatment/Coagulation-Flocculation.html [Accessed: 24.05.2019]

This website provides a summary of coagulation-flocculation sedimentation processes including combined technologies such as Flocculation-Chlorination.

This document compares the energy requirements for the removal of micropollutants in drinking water treatment plants by ozonation and O3/H2O2. The energy requirements for both treatments are in a similar range however O3/H2O2 reduces the contact time and bromated formation.

KATSOYANNIS, I.A. ; GUNTEN, U. von (n.y): Comparison of Energy Requirements of Conventional Ozonation and the AOP O3/H2O2 for Transformation of Target Micropollutants in Diverse Matrices . In: Techneau Deliverable D2: URL [Accessed: 23.05.2019]

Presentation on different ozone generators, processes design and monitoring.

SACCO, A. (2009): Ozone Water Treatment Application and Design. In: Spartan Environmental Technologies LLC.: URL [Accessed: 23.05.2019]

This chapter of EPA Guidance Manuel provides a lot of scientific information on Peroxone chemistry and applications such as disinfection and organics degradation.

EPA (1999): Peroxone (Ozone/Hydrogen Peroxide). In: EPA Guidance Manual, Alternative Disinfectants and Oxidants: URL [Accessed: 23.05.2019]

NEDERHOFF, E. (2000): Hydrogen Peroxide for Cleaning Irrigation System. In: Pathogen control in soilless cultures-part9 CropHouse (Editor): URL [Accessed: 23.05.2019]

This is a review article about ozonation in drinking water including many aspects such as ozone production, reaction mechanisms, applicability, price, safety, etc.

EAGLETON, J. (1999): Ozone in Drinking Water Treatment a Brief Overview 106 Years and Still Going. URL [Accessed: 23.05.2019]

DEED T. (1998): The Manufacture of Hydrogen Peroxide. In: Heather Wansbrough: URL [Accessed: 23.05.2019]

EPA (1999): Wastewater Technology Fact Sheet Ozone Disinfection. In: National Service Center for Environmental Publications (NSCEP): URL [Accessed: 23.05.2019]

AMIN, H. ; AMER, A. ; EL FECKY, A. ; IBRAHIM, I. (2008): Treatment of Textile Waste Water Using H2O2/UV System. In: Physicochemical Problems of Mineral Processing : Volume 42 , 17-28. URL [Accessed: 23.05.2019]

This article discusses the efficiency of UV/Hydrogen Peroxide and UV/Ozone treatments for the degradation of persistent organic contaminants including metabolite analysis and economic evaluation.

SONA, M. ; BAUS, C. ; BRAUCH, H.J. (2006): UV Irradiation Versus Combined UV/Hydrogen Peroxide and UV/Ozone Treatment for the Removal of Persistent Organic Pollutants from Water. In: International Conference Ozone and UV: , 69-76. URL [Accessed: 23.05.2019]

This presentation shows the benefits of combining ozone with nanofiltration for water treatment namely the reduction of membranes fouling.

KARNIK, B.S. ; CHEN, K.C. ; JAGLOWSKI, D.R. ; DAVIES S.H. ; BAUMANN, M.J. ; MASTEN S.J. (2004): Combined Ozonation-Nanofiltration for Drinking Water Treatment. In: United State Environmental Protection Agency: URL [Accessed: 23.05.2019]

This paper describes the treatment of a high pollution strength industrial wastewater with H2O2 combined with UV light and iron ions catalysts.

DINCER, A.R. ; KARAKAYA, N. ; GUNES, E. ; GUNES, Y. (2007): Removal of COD from Oil Recovery Industry Wastewater by the Advanced Oxidation Process (AOP) based on H2O2. In: Global NEST Journal : Volume 10 , 31-38. URL [Accessed: 23.05.2019]

This report describes the building up of a new simulator for chlorination and ozonation. It aims at giving a clear overview of the investigation fields related to modeling of oxidation for water purification. The model proposed is adaptable to on-site conditions.

MANDEL, P. (2007): Modelling of Micropollutant Removal by Ozonation and Chlorination in Potable Water Treatment. In: TECNEAU FP: Volume 6 URL [Accessed: 23.05.2019]

STUCKI, S. ; SCHULZE, D. ; SHUSTER, D. ; STARK, C. (2005): Ozonization of Purified Water Systems. In: Pharmaceutical Engineering: Volume 25 , 1-7. URL [Accessed: 23.05.2019]

DERCO, J. ; GULYASOVA, A. ; HORNAK, M. (2001): Influence of Ozonation on Biodegradability of Refractory Organics in a Landfill Leachate. In: Chemical Paper : Volume 56 , 41-44. URL [Accessed: 23.05.2019]

AL-KDASI, A. ; IDRIS, A. ; SAED, K. ; TEONG GUAN, C. (2004): Treatment of Textile Wastewater by Advanced Oxidation Processes- a Review. In: Global Nest: The International Journal : Volume 6 , 222-230. URL [Accessed: 23.05.2019]

This article outlines some key features of these membrane-based technologies and describes how they can be adapted to supply safe drinking water in remote communities and rural regions from the developing world.

FARCY, M. ; DOUCOURE, A. (2010): Membrane Systems for the Fight against Water-Borne Contaminants in Small Communities and Remote Areas from the Developing World: Accomplishments in Thailand and Some New Development in Sénégal and Mali . In: The Open Biology Journal: Volume 3 , 74-80. URL [Accessed: 22.05.2019]

This report presents a literature review on nanofiltration.

THORSEN, T. FLOGSTAD, H. (2006): Nanofiltration in Drinking Water Treatment. Nieuwegein, The Netherlands: Techneau URL [Accessed: 22.05.2019]