REFERENCES
- Lior, N. (2012) Advances in Water Desalination. John Wiley & Sons: Hoboken, NJ.
- Sethi, S., Walker, S., Drewes, J., and Xu, P. (2006) Existing and emerging concentrate minimization and disposal practices for membrane systems. Fla. Water Resour. J., 58: 38–48.
- Greenlee, L.F., Lawler, D.F, Freeman, B.D., Marrot, B., and Moulin, P. (2009) Reverse osmosis desalination: Water sources, technology, and today’s challenges. Water Res., 43: 2317–2348.
- Ahmed, M., Shayya, W.H., Hoey, D., Mahendran, A., Morris, R., and Al-Handaly, J. (2000) Use of evaporation ponds for brine disposal in desalination plants. Desalination, 130: 155–168.
- Muniz, A. and Skehan, S. (1990) Disposal of concentrate from brackish water desalting plants by use of deep injection wells. Desalination, 78: 41–47.
- Purnalna, A., Al-Barwani, H.H., and Al-Lawatia, M. (2003) Modeling dispersion of brine waste discharges from a coastal desalination plant. Desalination, 155: 41–47.
- Bashitialshaaer, R., Flyborg, L., and Persson, K.M. (2011) Environmental assessment of brine discharge and wastewater in the Arabian Gulf. Desalin. Water Treat, 25: 276–285.
- Nghiem, L.D. and Robertson, A. (2011) Treatment of high TDS liquid waste: Is zero liquid discharge feasible? Faculty of Engineering-Papers, Faculty of Engineering and Information Science, University of Wollongong, 1–11.
- Katzir, L., Volkmann, Y., Daltrophe, N., Korngold, E., Mesalem, R., Oren, Y., and Gilron, J. (2010) WAIV - Wind aided intensified evaporation for brine volume reduction and generating mineral byproducts. Desalin Water Treat., 13: 63–73.
- Younos, T. (2005) Environmental issues of desalination. J. Contemp. Water Res. Educ., 132: 11–18.
- Greenlee, L.F., Lawler, D.F., Freeman, B.D., Marrot, B., and Moulin, P. (2009) Reverse osmosis desalination: Water sources, technology, and today’s challenges. Water Res., 43: 2317–2348.
- Einav, R., Harussi, K., and Perry, D. (2003) The footprint of the desalination processes on the environment. Desalination, 152: 141–154.
- Roberts, D.A., Johnston, E.L., and Knott, N.A. (2010) Impacts of desalination plant discharges on the marine environment: A critical review of published studies. Water Res, 44: 5117–5128.
- Alharbi, O.A., Phillips, M.R., Williams, A.T., Gheith, A.M., Bantan, R.A., and Rasul, N.M. (2012) Desalination impacts on the coastal environment: Ash Shuqayq, Saudi Arabia. Sci. Total Environ., 421–422:163–172.
- Liu, T., Sheu, H., and Tseng, C. (2013) Environmental impact assessment of seawater desalination plant under the framework of integrated coastal management. Desalination, 326: 10–18.
- Ning, X., Lin, M., Shen, L., Zhang, J., Wang, J., Wang, Y., Yang, Z., and Liu, J. (2014) Levels, composition profiles and risk assessment of polycyclic aromatic hydrocarbons (PAHs) in sludge from ten textile dyeing plants. Environ. Res., 132: 112–118.
- Pérez-González, A., Urtiaga, A.M., Ibáñez, R., and Ortiz, I. (2012) State of the art and review on the treatment technologies of water reverse osmosis concentrates. Water Res., 46: 267–283.
- Morillo, J., Usero, J., Rosado, D., El Bakouri, H., Riaza, A., and Bernaola, F. (2014) Comparative study of brine management technologies for desalination plants. Desalination, 336: 32–49.
- Kim, D.H. (2011) A review of desalting process techniques and economic analysis of the recovery of salts from retentates. Desalination, 270: 1–8.
- Van Der Bruggen, B., Lejon, L., and Vandecasteele, C. (2003) Reuse, treatment, and discharge of the concentrate of pressure-driven membrane processes. Environ Sci Technol, 37: 3733–3738.
- Leong, J., Tan, J., Charrois, J., and Ladewig, B.P. (2013) Review of high recovery concentrate management options. Desalin. Water Treat., 52: 7609–7627.
- Xu, P., Cath, T.Y., Robertson, A.P., Reinhard, M., Leckie, J.O., and Drewes, J.E. (2013) Critical Review of desalination concentrate management, treatment and beneficial use. Environ. Eng. Sci., 30: 502–514.
- Tran, A.T.K., Mondal, P., Lin, J., Meesschaert, B., Pinoy, L., and Van der Bruggen, B. (2015) Simultaneous regeneration of inorganic acid and base from a metal washing step wastewater by bipolar membrane electrodialysis after pretreatment by crystallization in a fluidized pellet reactor. J. Membr. Sci., 473: 118–127.
- Wei, Y., Wang, Y., Zhang, X., and Xu, T. (2013) Comparative study on the treatment of simulated brominated butyl rubber wastewater by using bipolar membrane electrodialysis (BMED) and conventional electrodialysis (ED). Sep. Purif. Technol., 110: 164–169.
- Kumar, H. and Alén, R. (2014) Partial recovery of aliphatic carboxylic acids and sodium hydroxide from hardwood black liquor by electrodialysis. Ind. Eng. Chem. Res., 53: 9464–9470.
- Lameloise, M. and Lewandowski, R. (2012) Recovering l-malic acid from a beverage industry waste water: Experimental study of the conversion stage using bipolar membrane electrodialysis. J. Membr. Sci., 403–404:196–202.
- Zhang, X., Li, C., Wang, Y., Luo, J., and Xu, T. (2011) Recovery of acetic acid from simulated acetaldehyde wastewaters: Bipolar membrane electrodialysis processes and membrane selection. J. Membr. Sci., 379: 184–190.
- Lattemann, S. and Höpner, T. (2008) Environmental impact and impact assessment of seawater desalination. Desalination, 220: 1–15.
- Al-Shammiri, M., Safar, M., and Al-Dawas, M. (2000) Evaluation of two different antiscalants in real operation at the Doha research plant. Desalination, 128: 1–16.
- United Nations Environmental Programme (UNEP). (2008) Desalination Resource and Guidance Manual for Environmental Impact Assessments, UNEP/ROWA, Manama, and WHO/EMRO: Manana, Kingdom of Bahrain and Egypt.
- Sadhwani, J.J., Veza, J.M., and Santana, C. (2005) Case studies on environmental impact of seawater desalination. Desalination, 185: 1–8.
- Yang, Y., Gao, X., Fan, A., Fu, L., and Gao, C. (2014) An innovative beneficial reuse of seawater concentrate using bipolar membrane electrodialysis. J. Membr. Sci., 449: 119–126.
- Mezher, T., Fath, H., Abbas, Z., and Khaled, A. (2011) Techno-economic assessment and environmental impacts of desalination technologies. Desalination, 266: 263–273.
- Seawater Desalination Costs. White Paper. (2012) Water Reuse Association.
- Peinemann, K.-V. and Nunes, S.P. (2010) Membranes for Water Treatment, Vol. 4. Wiley-VCH: Weinheim.
- El–Sheikh, R., Shaban, M., and Jaber, I. (2010) Management of desalination plants and distribution options of desalinated water. Available at http://iwtc.info/wp-content/uploads/2010/09/Management-of-desalination-plants-and-distribution-options-of-desalinated-water.pdf ( accessed November 16, 2015).
- Zhang, Y., Ghyselbrecht, K., Vanherpe, R., Meesschaert, B., Pinoy, L., and Van der Bruggen, B. (2012) RO concentrate minimization by electrodialysis: Techno-economic analysis and environmental concerns. J. Environ. Manage., 107: 28–36.
- Safrai, I. and Zask, A. (2008) Reverse osmosis desalination plants — Marine environmentalist regulator point of view. Desalination, 220: 72–84.
- Ghaffour, N., Missimer, T.M., and Amy, G.L. (2013) Technical review and evaluation of the economics of water desalination: Current and future challenges for better water supply sustainability. Desalination, 309: 197–207.
- Del-Pilar-Ruso, Y., De-la-Ossa-Carretero, J.A., Giménez-Casalduero, F., and Sánchez-Lizaso, J.L. (2008) Effects of a brine discharge over soft bottom polychaeta assemblage. Environ. Pollut., 156: 240–250.
- Miri, R. and Chouikhi, A. (2005) Ecotoxicological marine impacts from seawater desalination plants. Desalination, 182: 403–410.
- Mauguin, G. and Corsin, P. (2005) Concentrate and other waste disposals from SWRO Plants: Characterization and reduction of their environmental impact. Desalination, 182: 355–364.
- Sánchez-Lizaso, J.L., Romero, J., Ruiz, J., Gacia, E., Buceta, J.L., Invers, O., Fernández Torquemada, Y., Mas, J., Ruiz-Mateo, A., and Manzanera, M. (2008) Salinity tolerance of the mediterranean Seagrass Posidonia Oceanica: Recommendations to minimize the impact of brine discharges from desalination plants. Desalination, 221: 602–607.
- Elimelech, M. and Phillip, W.A. (2011) The future of seawater desalination: Energy, technology, and the environment. Science, 333: 712–717.
- Abu Qdais, H. (2008) Environmental impacts of the mega desalination project: The Red–Dead sea conveyor. Desalination, 220: 16–23.
- Tsiourtis, N.X. (2001) Desalination and the environment. Desalination, 141: 223–236.
- European Commision Environment. http://ec.europa.eu/environment/eia/eia-legalcontext.htm ( accessed November 16, 2015).
- Stokes, J. and Horvath, A. (2006) Life cycle energy assessment of alternative water supply systems. Int. J. Life Cycle Ass., 11: 335–343.
- Del Borghi, A., Strazza, C., Gallo, M., Messineo, S., and Naso, M. (2013) Water supply and sustainability: Life cycle assessment of water collection, treatment and distribution service. Int. J. Life Cycle Ass., 18: 1158–1168.
- Xu, T. (2005) Ion exchange membranes: State of their development and perspective. J. Membr. Sci., 263: 1–29.
- Mier, M.P., Ibañez, R., and Ortiz, I. (2008) Influence of ion concentration on the kinetics of electrodialysis with bipolar membranes. Sep. Purif. Technol., 59: 197–205.
- Fernandez-Gonzalez, C., Dominguez-Ramos, A., Ibañez, R., and Irabien, A. (2015) Sustainability assessment of electrodialysis powered by photovoltaic solar energy for freshwater production. Renew Sust. Energ. Rev., 47: 604–615.
- Kentish, S.E., Kloester, E., Stevens, G.W., Scholes, C.A., and Dumée, L.F. (2015) Electrodialysis in aqueous-organic mixtures. Sep. Purif. Rev., 44: 269–282.
- Kumar, M., Khan, M.A., Al-Othman, Z.A., and Choong, T.S.Y. (2013) Recent developments in ion-exchange membranes and their applications in electrochemical processes for in situ ion substitutions, separation and water splitting. Sep. Purif. Rev., 42: 187–261.
- Huang, C. and Xu, T. (2006) Electrodialysis with bipolar membranes for sustainable development. Environ. Sci. Technol., 40: 5233–5243.
- Badruzzaman, M., Oppenheimer, J., Adham, S., and Kumar, M. (2009) Innovative beneficial reuse of reverse osmosis concentrate using bipolar membrane electrodialysis and electrochlorination processes. J. Membr. Sci., 326: 392–399.
- Ibáñez, R., Pérez-González, A., Gómez, P., Urtiaga, A.M., and Ortiz, I. (2013) Acid and base recovery from softened reverse osmosis (RO) brines. Experimental assessment using model concentrates. Desalination, 309: 165–170.
- Mavrov, V., Chmiel, H., Heitele, B., and Rögener, F. (1999) Desalination of surface water to industrial water with lower impact on the environment: Part 4: Treatment of effluents from water desalination stages for reuse and balance of the new technological concept for water desalination. Desalination, 124: 205–216.
- Wang, M., Wang, K, Jia, Y., and Ren, Q. (2014) The reclamation of brine generated from desalination process by bipolar membrane electrodialysis. J. Membr. Sci., 452: 54–61.
- Wang, X., Wang, M., Jia, Y., and Yao, T. (2012) The feasible study on the reclamation of the glyphosate neutralization liquor by bipolar membrane electrodialysis. Desalination, 300: 58–63.
- Shen, J., Huang, J., Liu, L., Ye, W., Lin, J., and Van der Bruggen, B. (2013) The use of BMED for glyphosate recovery from glyphosate neutralization liquor in view of zero discharge. J. Hazard. Mater., 260: 660–667.
- Ghyselbrecht, K., Huygebaert, M., Van der Bruggen, B., Ballet, R., Meesschaert, B., and Pinoy, L. (2013) Desalination of an industrial saline water with conventional and bipolar membrane electrodialysis. Desalination, 318: 9–18.
- Ghyselbrecht, K., Silva, A., Van der Bruggen, B., Boussu, K., Meesschaert, B., and Pinoy, L. (2014) Desalination feasibility study of an industrial NaCl stream by bipolar membrane electrodialysis. J. Environ. Manage., 140: 69–75.
- Gao, X., Yang, Y., Fu, L., Sun, Z., Zheng, Y., and Gao, C. (2014) Regenerating spent acid produced by HZSM-5 zeolite preparation by bipolar membrane electrodialysis. Sep. Purif. Technol., 125: 97–102.
- Davis, J.R., Chen, Y, Baygents, J.C., and Farrell, J. (2015) Production of acids and bases for ion exchange regeneration from dilute salt solutions using bipolar membrane electrodialysis. ACS Sustain. Chem. Eng., 3: 2337–2342.
- Lin, J., Ye, W., Huang, J., Ricard, B., Baltaru, M., Greydanus, B., Balta, S., Shen, J., Vlad, M., Sotto, A., Luis, P., and Van Der Bruggen, B. (2015) Toward resource recovery from textile wastewater: Dye extraction, water and base/acid regeneration using a hybrid NF-BMED process. ACS Sustain. Chem. Eng., 3: 1993–2001.
- Strathmann, H. (2010) Electrodialysis, a mature technology with a multitude of new applications. Desalination, 264: 268–288.
- Pérez-González, A., Ibáñez, R., Gómez, P., Urtiaga, A.M., Ortiz, I., and Irabien, J.A. (2015) Nanofiltration separation of polyvalent and monovalent anions in desalination brines. J. Membr. Sci., 473: 16–27.
- Ye, W., Huang, J., Lin, J., Zhang, X., Shen, J., Luis, P., and Van Der Bruggen, B. (2015) Environmental evaluation of bipolar membrane electrodialysis for NaOH production from wastewater: Conditioning NaOH as a CO2 absorbent. Sep. Purif. Technol., 144: 206–214.
- Pérez-González, A., Ibáñez, R., Gómez, P., Urtiaga, A., Ortiz, I., and Irabien, J. (2015) Recovery of desalination brines: Separation of calcium, magnesium and sulfate as a pre-treatment step. Desalin Water Treat, 56: 3617–3625.
- Venugopal, K. and Dharmalingam, S. (2012) Desalination efficiency of a novel bipolar membrane based on functionalized polysulfone. Desalination, 296: 37–45.
- Xu, T. and Huang, C. (2008) Electrodialysis-based separation technologies: A critical review. AIChE J., 54: 3147–3159.
- Fumatech. http://www.fumatech.com/EN/ ( accessed November 16, 2015).
- Zabolotskii, V., Sheldeshov, N., and Melnikov, S. (2014) Heterogeneous bipolar membranes and their application in electrodialysis. Desalination, 342: 183–203.
- Burges, K. (2003) Pv powered desalination. The Middle East Desalination Research Centre (MEDRC): Sultanate of Oman.
- Xu, T. (2005) Ion exchange membranes: State of their development and perspective. J. Membr. Sci., 263: 1–29.
- Kim, D.J., Jeong, M.K., and Nam, S.Y. (2015) Research trends in ion exchange membrane processes and practical applications. Appl. Chem. Eng., 26: 1–16.
- Tongwen, X. (2002) Electrodialysis processes with bipolar membranes (EDBM) in environmental protection—A review. Resour. Conserv Recyc., 37: 1–22.
- PCC Morava Chem. Technical and food grade hydrochloric acid. http://www.pccmorava-chem.cz/ttw/mch.nsf/id/EN_Hydrochloric_acid_%28food_grade,_technical_grade%29 ( accessed November 16, 2015).
- Hubei Sanonda. High purity hydrochloric acid. http://www.sld.chemchina.com/slden/cpyfw/ppysb/chjyzyhxp/webinfo/2012/07/1342611934400944.htm ( accessed November 16, 2015).
- PPG. Muriatic acid. http://www.ppg.com/chemicals/chloralkali/documents/english/muriaticacid.pdf ( accessed November 16, 2015).
- Reagent chemical. Food grade Hydrochloric acid 20 degree. http://www.reagentchemical.com/documents/HCL_Food_Grade_20.pdf ( accessed November 16, 2015).
- Reagent chemical. Food grade Hydrochloric acid 22 degree. http://www.reagentchemical.com/documents/HCL_Food_Grade_22.pdf ( accessed November 16, 2015).
- Covestro. Liquid caustic soda. http://www.polyurethanes.covestro.com/Handler/GenericForceDownload.ashx?itemID=C5BD0BD550D2441DAA28177D1BA4E756&lang=en ( accessed November 16, 2015).
- Colonial Chemical Solutions. Commercial grade caustic soda. http://colonialchemicals.com/uploads/Products/Caustic%20Soda%20-%20Rayon%20Grade/Caustic%20Soda%20RG_Tech.pdf ( accessed November 16, 2015).
- NPC Chlorochem. Membrane cell caustic soda. http://www.ncp.co.za/product/detail/2/caustic-soda-lye-naoh ( accessed November 16, 2015).
- Olin. Diaphragm cell and membrane cell Caustic Soda. http://www.olinchloralkali.com/en-us/ ( accessed November 16, 2015).
- Siping Haohua Chemical. High purity sodium hydroxide. http://www.hhsp.chemchina.com/sphhen/cpyfw/ppysb/webinfo/2012/05/1339060894928029.htm ( accessed November 16, 2015).
- Vinythai. Caustic soda liquid. http://www.solvay.com/en/index.html ( accessed November 16, 2015).