References

  1. B.E. Logan, The global challenge of sustainable seawater desalination, Environ. Sci. Technol. Lett., 4 (2017) 197.
  2. M. Elimelech, W.A. Phillip, The future of seawater desalination: energy, technology, and the environment, Science, 333 (2011) 712–717.
  3. B.I. Escher, M. Lawrence, M. Macova, J.F. Mueller, Y. Poussade, C. Robillot, A. Roux, W. Gernjak, Evaluation of contaminant removal of reverse osmosis and advanced oxidation in fullscale operation by combining passive sampling with chemical analysis and bioanalytical tools, Environ. Sci. Technol., 45 (2011) 5387–5394.
  4. C.-L. de O. Manes, C. Barbe, N.J. West, S. Rapenne, P. Lebaron, Impact of seawater-quality and water treatment procedures on the active bacterial assemblages at two desalination sites, Environ. Sci. Technol., 45 (2011) 5943–5951.
  5. L.F. Greenlee, D.F. Lawler, B.D. Freeman, B. Marrot, P. Moulin, Reverse osmosis desalination: water sources, technology, and today’s challenges, Water Res., 43 (2009) 2317–2348.
  6. J. Zhou, V.W.-C. Chang, A.G. Fane, Life cycle assessment for desalination: a review on methodology feasibility and reliability, Water Res., 61 (2014) 210–223.
  7. X. Zheng, D. Chen, Q. Wang, Z.X. Zhang, Seawater desalination in China: retrospect and prospect, Chem. Eng. J., 242 (2014) 404–413.
  8. Q.R. Zou, X.L. Liu, Economic effects analysis of seawater desalination in China with input–output technology, Desalination, 380 (2016) 18–28.
  9. Y.S. Ovadia, D. Gefel, D. Aharoni, S. Turkot, S. Fytlovich, A.M. Troen, Can desalinated seawater contribute to iodinedeficiency disorders? An observation and hypothesis, Public Health Nutr., 19 (2016) 2808–2817.
  10. O. Lahav, B.H. Liat, Quality criteria for desalinated water following post-treatment, Desalination, 207 (2007) 286–303.
  11. M. Shlezinger, Y. Amitai, I. Goldenberg, M. Shechter, Desalinated seawater supply and all-cause mortality in hospitalized acute myocardial infarction patients from the Acute Coronary Syndrome Israeli Survey 2002–2013, Int. J. Cardiol., 220 (2016) 544–550.
  12. A. Belila, J. El-Chakhtoura, N. Otaibi, G. Muyzer, G. Gonzalez- Gil, P.E. Saikaly, M.C.M. van Loosdrecht, J.S. Vrouwenvelder, Bacterial community structure and variation in a full-scale seawater desalination plant for drinking water production, Water Res., 94 (2016) 62–72.
  13. D.Y. Kim, G.L. Amy, T. Karanfil, Disinfection by-product formation during seawater desalination: a review, Water Res., 81 (2015) 343–355.
  14. J.K. Edzwald, J. Haarhoff, Seawater pretreatment for reverse osmosis: chemistry, contaminants, and coagulation, Water Res., 45 (2011) 5428–5440.
  15. M. Rygaard, E. Arvin, P.J. Binning, The valuation of water quality: effects of mixing different drinking water qualities, Water Res., 43 (2009) 1207–1218.
  16. J. Radjenović, M. Petrović, F. Ventura, D. Barceló, Rejection of pharmaceuticals in nanofiltration and reverse osmosis membrane drinking water treatment, Water Res., 42 (2008) 3601–3610.
  17. X.-N. Wang, Y. Liu, X.-H. Pan, J.-X. Han, J. Hao, Parameters for seawater reverse osmosis product water: a review, Exposure Health, 9 (2017) 157–168.
  18. Q.F. Yang, Y.Q. Liu, Y.J. Li, Humic acid fouling mitigation by antiscalant in reverse osmosis system, Environ. Sci. Technol., 44 (2010) 5153–5158.
  19. D. Prats, M.F. Chillon-Arias, M. Rodriguez-Pastor, Analysis of the influence of pH and pressure on the elimination of boron in reverse osmosis, Desalination, 128 (2000) 269–273.
  20. B. Teychene, G. Collet, H. Gallard, J.-P. Croue, A comparative study of boron and arsenic (III) rejection from brackish water by reverse osmosis membranes, Desalination, 310 (2013) 109–114.
  21. N. Avni, M. Eben-Chaime, G. Oron, Optimizing desalinated sea water blending with other sources to meet magnesium requirements for potable and irrigation waters, Water Res., 47 (2013) 2164–2176.
  22. I.G. Wenten, Khoiruddin, Reverse osmosis applications: prospect and challenges, Desalination, 391 (2016) 112–125.
  23. J.R. Werber, A. Deshmukh, M. Elimelech, The critical need for increased selectivity, not increased water permeability, for desalination membranes, Environ. Sci. Technol. Lett., 3 (2016) 1–29.
  24. K.L. Tu, T. Fujioka, S.J. Khan, Y. Poussade, A. Roux, J.E. Drewes, A.R. Chivas, L.D. Nghiem, Boron as a surrogate for N-nitrosodimethylamine rejection by reverse osmosis membranes in potable water reuse applications, Environ. Sci. Technol., 47 (2013) 6425–6430.
  25. B. Peñate, L. García-Rodríguez, Current trends and future prospects in the design of seawater reverse osmosis desalination technology, Desalination, 284 (2012) 1–8.
  26. K. Rahmawati, N. Ghaffour, C. Aubry, G.L. Amy, Boron removal efficiency from Red Sea water using different SWRO/BWRO membranes, J. Membr. Sci., 423–424 (2012) 522–529.
  27. A. Alpatova, A. Alsaadi, N. Ghaffour, Boron evaporation in thermally-driven seawater desalination: effect of temperature and operating conditions, J. Hazard. Mater., 351 (2018) 224–231.
  28. S. Jeong, G. Naidu, R. Vollprecht, T. Leiknes, S. Vigneswaran, In-depth analyses of organic matters in a full-scale seawater desalination plant and an autopsy of reverse osmosis membrane, Sep. Purif. Technol., 162 (2016) 171–179.
  29. H.-W. Yu, S.-G. Oh, I.S. Kim, I. Pepper, S. Snyder, A. Jang, Formation and speciation of haloacetic acids in seawater desalination using chlorine dioxide as disinfectant, J. Ind. Eng. Chem., 26 (2015) 193–201.
  30. E. Agus, N. Voutchkov, D.L. Sedlak, Disinfection by-products and their potential impact on the quality of water produced by desalination systems: a literature review, Desalination, 237 (2009) 214–237.