References

1. K.S. Spiegler, Y.M. El-Sayed, A Desalination Primer, Italy: Balaban Desalination Publications, 1994.
2. P. Williams, M. Ahmad, B. Connolly, D. Oatley, Technology for freeze concentration in the desalination industry, Desalination, 356 (2015) 314–327.
3. M. Mulder, Basic Principles of Membrane Technology, 2nd ed., Netherlands: Kluwer Academic Publishers, 1996.
4. O.K. Buros, ABCs of Desalting, 2nd ed. S.I., Topsfield, Massachusetts, United States of America: International Desalination Association (IDA), 2000.
5. A. Cipollina, G. Micale, L. Rizzuti, Seawater Desalination: Conventional and Renewable Energy Processes (Green Energy and Technology), Springer, Springer-Verlag Berlin and Heidelberg GmbH & Co. KG., 2009.
6. R. Clayton, Desalination for Water Supply, FR/R0013, Foundation for Water Research, 2011.
7. A.D. Khawaji, I.K. Kutubkhanah, J.M. Wie, Advances in seawater desalination technologies, Desalination, 221 (2008) 47–69.
8. J.E. Miller, Review of Water Resources and Desalination Technologies, Sand Report, Sandia National Laboratories, 2003.
9. 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.
10. M.L. Stone, C. Rae, F.F. Stewart, A.D. Wilson, Switchable polarity solvents as draw solutes for forward osmosis, Desalination, 312 (2013) 124–129.
11. M. Ahmad, Assessment of Freeing Desalination Technologies, PhD Thesis, Swansea University, 2012.
12. Q. Ge, M. Ling, T.S. Chung, Draw solutions for forward osmosis processes: developments, challenges, and prospects for future, J. Membr. Sci., 442 (2013) 225–237.
13. B. Van der Bruggen, L. Lejon, C. Vandecasteele, Reuse, treatment, and discharge of the concentrate of pressure-driven membrane processes, Environ. Sci. Technol., 37 (2003) 3733–3738.
14. G. Nebbia, G. Menozzi, Early experiments on water desalination by freezing, Desalination, 5 (1968) 49–54.
15. W. Johnson, State-of-the-art of freezing processes, their potential and future, Desalination, 19 (1976) 349–358.
16. A. Rich, M. Youssef, B. Nourimane, M. Denis, A. Souad, B. Christine, S. Naoual, K. Jean-Paul, B. Tijani, B. Ahmed, V. Stephane, Freezing desalination of seawater in a static layer crystallizer, Desalination, 269 (2011) 142–147.
17. K.S. Spiegler, A.D.K. Laird, Principles of desalination “Part A,” 2nd ed., London: Academic Press INC., Vol. 1, 1980.
18. W.E. Johnson, Indirect freezing, Desalination, 31 (1979) 417–425.
19. D. Randall, J. Nathoo, A succinct review of the treatment of reverse osmosis brines using freeze crystallization, J. Water Process Eng., 8 (2015) 186–194.
20. W. Goa, Y. Shao, Freeze concentration for removal of pharmaceutically active compounds in water, Desalination, 249 (2009) 398–402.
21. F. Melak, G. Du Laing, A. Ambelu, E. Alemayehu, Application of freeze desalination for chromium (VI) removal from water, Desalination, 377 (2016) 23–27.
22. K. Kang, P. Linga, K. Park, S.-J. Choi, J. Lee, Seawater desalination by gas hydrate process and removal characteristics of dissolved ions (Na⁺, K⁺, Mg²⁺, Ca²⁺, B²⁺, Cl^–, SO₄^2–), Desalination, 353 (2014) 84–90.
23. P.L.T. Brian, Potential advantages and development problems in water desalination by freezing, Chem. Eng., 78 (1971) 191–197.
24. W. Cao, C. Beggs, I. Mujtaba, Theoretical approach of freeze seawater desalination on flake ice maker utilizing LNG cold energy, Desalination, 355 (2015) 22–32.
25. P. Wang, T. Chung, A conceptual demonstration of freeze desalination membrane distillation (FD-MD) hybrid desalination process utilizing liquefied natural gas (LNG) cold energy, Water Res., 46 (2012) 4037–4052.
26. J.A. Heist, Freeze crystallization, Chem. Eng., 86 (1979) 72–82.
27. R. Halde, Concentration of impurities by progressive freezing, Water Res., 14 (1980) 575–580.
28. N. Fletcher, The freezing of water, Sci. Prog., 54 (1966) 227–241.
29. R. Fujioka, L. Wang, G. Dodbiba, T. Fujita, Application of progressive freeze-concentration for desalination, Desalination, 319 (2013) 33–37.
30. A. Attia, New proposed system for freeze water desalination using auto reversed R-22 vapor compression heat pump, Desalination, 254 (2010) 179–184.
31. M. Rahman, M. Ahmed, Freezing melting process and desalination: I. Review of the state of the art, Separ. Purif. Rev., 35 (2006) 59–96.
32. C. Agnew, E. Anderson, Water Resources in the Arid Realm, Rutledge, London, 1992.
33. R.W. Hartel, Evaporation and Freeze Concentration, D.R. Heldman, D.B. Lund (Eds.) Handbook of Food Engineering, New York: Marcel Dekker, 1992, pp. 341–392.
34. W.E. Johnson, State-of-the-art of freezing processes, their potential and future, Desalination, 19 (1976) 349–358.
35. J.B. Maguire, Fresh water from the sea, a new process, Desalination, 67 (1987) 155–162.
36. M. Rahman, M. Ahmed, X. Chen, Freezing–melting process and desalination: review of present status and future prospects, Int. J. Nucl. Desal., 2 (2007) 253–264.
37. P.J. Schroeder, A.S. Chan, A.R. Khan, Freezing processes – the standard of the future, Desalination, 21 (1977) 125–136.
38. J.G. Muller, Freeze concentration of liquids: theory, practice and economics, Food Technol., 21 (1967) 49–60.
39. Energy Requirements of Desalination Processes, Encyclopedia of Desalination and Water Resources (DESWARE). Available at: http://www.desware.net/Energy-Requirements-Desalination-Processes.aspx
40. M. Ahmad, P. Williams, Assessment of desalination technologies for high saline brine applications – discussion paper, Desalination, 30 (2011) 22–36.
41. K.S. Spiegler, Principles of Desalination, London: Academic Press, 1966.
42. R.J. Braddock, J.E. Marcy, Quality of freeze concentrated orange juice, J Food Sci., 52 (1987) 159–162.
43. S. Lemmer, R. Klomp, R. Ruemekorf, R. Scholz, Preconcentration of wastewater through the Niro freeze concentration process, Chem. Eng. Technol., 24 (2001) 485–488.
44. G. Lofrano, S. Meriç, G.E. Zengin, D. Orhon, Chemical and biological treatment technologies for leather tannery chemicals and wastewaters: a review, Sci. Total Environ., 461–462 (2013) 265–281.
45. M. Gunathilake, M. Dozen, K. Shimmura, O. Miyawaki, An apparatus for partial ice melting to improve yield in progressive freeze-concentration, J. Food Eng., 142 (2014) 64–69.
46. M. Mahdavi, A.H. Mahvi, S. Nasseri, M. Yunesian, Application of freezing to the desalination of saline water, Arab. J. Sci. Eng., 36 (2011) 1171–1177.
47. Z. Lu, L. Xu, Freezing Desalination Process, Thermal Desalination Process, Vol. II, 2010.
48. J. Ulrich, H. Glade, Melt crystallisation, Germany: Shaker Verlag, 2003.
49. A.J. Barduhn, Freezing Processes for Water Conversion in the United States, First International Symposium on Water Desalination, 3–9 October 1965, Washington D.C., USA.
50. D. Randall, J. Nathoo, F. Genceli-Guner, H. Kramer, G. Witkamp, A. Lewis, Determination of the metastable ice zone for a sodium sulphate system, Chem. Eng. Sci., 77 (2012) 184–188.
51. F. Van der Ham, G.J. Witkamp, J. de Graauw, G.M. van Rosmalen, Eutectic freeze crystallization: application to process streams and waste water purification, Chem. Eng. Process., 37 (1998) 207–213.
52. A. Rich, Y. Mandri, N. Bendaoud, D. Mangin, S. Abderafi, C. Bebon, N. Semlali, J. Klein, T. Bounahmidi, A. Bouhaouss, S. Veesler, Freezing desalination of sea water in a static layer crystallizer, Desal. Wat. Treat., 13 (2010) 120–127.
53. A. Myerson, Handbook of Industrial Crystallization, 2nd ed., Butterworth-Heinemann, USA, 2002.
54. J. Burton, R. Prim, W. Slichter, The distribution of solute in crystals grown from the melt. Part I. Theoretical, J. Chem. Phys., 21 (1953) 1987–1996.
55. L. Wilson, A new look at the Burton, Prim and Slichter model of segregation during crystal growth from the melt, J. Crystal Growth, 44 (1978) 371–376.
56. F. Rosenberger, Fundamentals of Crystal Growth. Macroscopic Equilibrium and Transport Concepts, New York, Springer-Verlag, 1979, ISBN 3-540-09023-1.
57. K. Kim, S. Lee, J. Ulrich, Experimental thermal conductivity of ice crystalline layer in layer melt crystallization, J. Ind. Eng. Chem., 9 (2003) 111–116.
58. R. Halde, Concentration of impurities by progressive freezing, Water Res., 14 (1980) 575–580.
59. W.F. Weeks, S.F. Ackley, The Growth, Structure and Properties of Sea Ice, The Geophysics of Sea Ice, (1986) 9–164.
60. A. Rich, M. Siniti, D. Mangin, J. Klein, Y. Mandri, T. Bounahmidi, A. Bouhaouss, S. Veesler, M. El-Ganaoui, Study of a melt crystallization process for seawater desalination, J. Mech. Eng. Autom., 5 (2015) 45–52.
61. J. Ulrich, S.J. Jancic, A.K. Kuszlik, The Effect of Dissipative Mixing on Separation Efficiency of Progressive Freezing of Organic Melts, Proc. 11th Symposium on Industrial Crystallization, A. Mersmann (Ed.), Garmisch-Partenkirchen/Germany, 18, 1990, pp. 815–820.
62. H. Li, H. Li, Z. Guo, Y. Liu, The application of power ultrasound to reaction crystallization, Ultrason. Sonochem., 13 (2006) 359–363.
63. A. Mortazavi, F. Tabatabaie, Study of ice cream freezing process after treatment with ultrasound, World Appl. Sci. J., 4 (2008) 188–190, ISSN 1818-4952.
64. M. Mohamed, Solidification of phase change material on vertical cylindrical surface in holdup air bubbles, Int. J. Refrige., 28 (2005) 403–411.