References

  1. W.W. Choi, K.Y. Chen, Evaluation of boron removal by adsorption on solids, Environ. Sci. Technol., 13 (1979) 189–196.
  2. S. Sahin, A mathematical relationship for the explanation of ion exchange for boron adsorption, Desalination, 143 (2002) 35–43.
  3. K.L. Tu, L.D. Nghiem, A.R. Chivas, Boron removal by reverse osmosis membranes in seawater desalination applications, Sep. Purif. Technol., 75 (2010) 87–101.
  4. N. Hilal, G.J. Kim, C. Somerfield, Boron removal from saline water: a comprehensive review, Desalination, 273 (2011) 23–35.
  5. I.Y. Ipek, N. Kabay, M. Yuksel, Modeling of fixed bed column studies for removal of boron from geothermal water by selective chelating ion exchange resins, Desalination, 310 (2013) 151–157.
  6. E.B. Simsek, U. Beker, B.F. Senkal, Predicting the dynamics and performance of selective polymeric resins in a fixed bed system for boron removal, Desalination, 349 (2014) 39–50.
  7. J. Kluczka, T. Korolewicz, M. Zolotajkin, J. Adamek, Boron removal from water and wastewater using new polystyrene-based resin grafted with glycidol, Water Resour. Ind., 11 (2015) 46–57.
  8. M.M. Nasef, M. Nallappan, Z. Ujang, Polymer-based chelating adsorbents for the selective removal of boron from water and wastewater: a review, React. Funct. Polym., 85 (2014) 54–68.
  9. C. Jacob, Seawater desalination: boron removal by ion exchange technology, Desalination, 205 (2007) 47–52.
  10. P. Glueckstern, M. Priel, Optimization of boron removal in old and new SWRO systems, Desalination, 156 (2003) 219–228.
  11. N. Nadav, Boron removal from seawater reverse osmosis permeate utilizing selective ion exchange resin, Desalination, 124 (1999) 131–135.
  12. N. Kabay, S. Sarp, M. Yuksel, O. Arar, M. Bryjak, Removal of boron from seawater by selective ion exchange resins, React. Funct. Polym., 67 (2007) 1643–1650.
  13. N. Kabay, S. Sarp, M. Yuksel, M. Kitis, H. Koseoglu, O. Arar, M. Bryjak, R. Semiat, Removal of boron from SWRO permeate by boron selective ion exchange resins containing N-methyl glucamine group, Desalination, 223 (2008) 49–56.
  14. M.F.C. Arias, L.V. i Bru, D.P. Rico, P.V. Galvan, Comparison of ion exchange resins used in reduction of boron in desalinated water for human consumption, Desalination, 278 (2011) 244–249.
  15. N.B. Darwish, V. Kochkodan, N. Hilal, Boron removal from water with fractionized Amberlite IRA743 resin, Desalination, 370 (2015) 1–6.
  16. M. Garcia-Soto, E.M. Camacho, Boron removal from industrial wastewaters by ion exchange: an analytical control parameter, Desalination, 181 (2005) 207–216.
  17. M. Simonnot, C. Castel, M. Nicolai, C. Rosin, M. Sardin, H. Jauffret, Boron removal from drinking water with a boron selective resin: is the treatment really selective?, Water Res., 34 (2000) 109–116.
  18. A.E. Yilmaz, R. Boncukcuoglu, M.T. Yilmaz, M.M. Kocakerim, Adsorption of boron from boron-containing wastewaters by ion exchange in a continuous reactor, J. Hazard. Mater., 117 (2005) 221–226.
  19. H. Parschova, E. Mistova, Z. Matejka, L. Jelinek, N. Kabay, P. Kauppinen, Comparison of several polymeric sorbents for selective boron removal from reverse osmosis permeate, React. Funct. Polym., 67 (2007) 1622–1627.
  20. I.Y. Mohammed, K. Garba, S.D. Mandara, A.M. Saba, U.D. Sule, M. Ahmed, Comparative study of boron removal from reverse osmosis permeate using ion exchange resins, Int. J. Emerging Trends Eng. Dev., 4 (2014) 462–475.
  21. Dow Chemical Company, Lab Guide: Column Separations Using Resins and Adsorbents. Available at: http://msdssearch.dow.com/PublishedLiteratureDOWCOM/dh_015a/0901b8038015ac4e.pdf
  22. Dow Chemical Company, Product Data Sheet: Amberlite PWA10 Resin. Available at: http://msdssearch.dow.com/PublishedLiteratureDOWCOM/dh_08d1/0901b803808d1c1a.pdf?filepath=liquidseps/pdfs/noreg/177-03078.pdf&fromPage=GetDoc
  23. Dow Chemical Company, Material Safety Data Sheet: Amberlite PWA10 Ion Exchange Resin. Available at: http://www.dow.com/en-US/ShowPDF.ashx?id=090003e8806ff183
  24. Purolite, Engineering Bulletin: Purolite S108, Available at: http://www.purolite.com/dam/jcr: 944eb48c-b0be-40c0-acd5-c9e6db9306ff/S108%20Engineering%20Bulletin.pdf
  25. Lanxess, Product Information: Lewatit MK51, Available at: http://www.lenntech.com/Data-sheets/Lewatit-MK-51-L.pdf
  26. R. Han, Y. Wang, X. Zhao, Y. Wang, F. Xie, J. Cheng, M. Tang, Adsorption of methylene blue by phoenix tree leaf powder in a fixed-bed column: experiments and prediction of breakthrough curves, Desalination, 245 (2009) 284–297.
  27. I.J. Vassilis, Ion exchange and adsorption fixed bed operations for wastewater treatment – part I: modeling fundamentals and hydraulics analysis, J. Eng. Stud. Res., 16 (2010) 29–41.
  28. P.R. Rout, R.R. Dash, P. Bhunia, Modelling and packed bed column studies on adsorptive removal of phosphate from aqueous solutions by a mixture of ground burnt patties and red soil, Adv. Environ. Res., 3 (2014) 231–251.
  29. M. Trgo, N.V. Medvidovic, J. Peric, Application of mathematical empirical models to dynamic removal of lead on natural zeolite clinoptilolite in a fixed bed column, Indian J. Chem. Technol., 18 (2011) 123–131.
  30. L. Lapidus, N.R. Amundson, Mathematics of adsorption in beds. VI. The effect of longitudinal diffusion in ion exchange and chromatographic columns, J. Phys. Chem., 56 (1952) 984–988.
  31. H. Qiu, L. Lv, B. Pan, Q. Zhang, W. Zhang, Q. Zhang, Critical review in adsorption kinetic models, J. Zhejiang Univ. Sci. A, 10 (2009) 716–724.
  32. L. Largitte, R. Pasquier, A review of the kinetics adsorption models and their application to the adsorption of lead by an activated carbon, Chem. Eng. Res. Des., 109 (2016) 495–504.
  33. E. Malkoc, Y. Nuhoglu, Removal of Ni(II) ions from aqueous solutions using waste of tea factory: adsorption on a fixed-bed column, J. Hazard. Mater., 135 (2006) 328–336.
  34. I.J. Vassilis, Ion exchange and adsorption fixed bed operations for wastewater treatment – part II: scale-up and approximate design methods, J. Eng. Stud. Res., 16 (2010) 42–50.
  35. A. Negrea, L. Lupa, M. Ciopec, P. Negrea, Experimental and modeling studies on As(III) removal from aqueous medium on fixed bed column, Chem. Bull. “Politehnica” Univ. (Timisoara), 56 (2011) 89–93.
  36. A.A. Hekmatzadeh, A. Karimi-Jashani, N. Talebbeydokhti, B. Klove, Modeling of nitrate removal for ion exchange resin in batch and fixed bed experiments, Desalination, 284 (2012) 22–31.
  37. A.B. Albadarin, C. Mangwandi, A.H. Al-Muhtaseb, G.M. Walker, S.J. Allen, N.M. Ahmad, Modelling and fixed bed column adsorption of Cr(VI) onto orthophosphoric acidactivated lignin, Chin. J. Chem. Eng., 20 (2012) 469–477.
  38. J.T. Nwabanne, P.K. Igbokwe, Adsorption performance of packed bed column for the removal of lead (II) using oil palm fibre, Int. J. Appl. Sci. Technol., 2 (2012) 106–115.
  39. J.M.P.Q. Delgado, A critical review of dispersion in packed beds, Heat Mass Transfer, 42 (2006) 279–310.
  40. A.M. Kennedy, A.M. Reinert, D.R.U. Knappe, I. Ferrer, R.S. Summers, Full- and pilot-scale GAC adsorption of organic micropollutants, Water Res., 68 (2015) 238–248.
  41. Y. Wu, M.R. Khadilkar, M.H. Al-Dahhan, M.P. Dudukovic, Comparison of upflow and downflow two-phase flow packedbed reactors with and without fines: experimental observations, Ind. Eng. Chem. Res., 35 (1996) 397–405.