References

  1. K.I. Popov, N.E. Kovaleva, G. Ya. Rudakova, S.P. Kombarova, V.E. Larchenko, Recent state-of-the-art of biodegradable scale inhibitors for cooling-water treatment applications (review), Therm. Eng., 63 (2016) 122–129.
  2. J. MacAdam, S.A. Parsons, Calcium carbonate scale formation and control, Rev. Environ. Sci. Biotechnol., 3 (2004) 159–169.
  3. Z. Amjad, P.G. Koutsoukos, Evaluation of maleic acid based polymers as scale inhibitors and dispersants for industrial water applications, Desalination, 335 (2014) 55–63.
  4. M.K. Jensen, M.A. Kelland, A new class of hyperbranched polymeric scale inhibitors, J. Pet. Sci. Eng., 94–95 (2012) 66–72.
  5. Scale Inhibitor Market by Type and by Application - Global Trends and Forecast to 2019. Available from: http://www. researchandmarkets.com/reports/2933881/scale-inhibitormarket-by-type-and-by-application#pos-0
  6. D. Hasson, H. Shemer, A. Sher, State of the art of friendly “green” scale inhibitors: a review rrticle, Ind. Eng. Chem. Res., 50 (2011) 7601–7607.
  7. M. Chaussemier, E. Pourmohtasham, D. Gelus, N. Pécoul, H. Perrot, J. Lédion, H. Cheap-Charpentier, O. Horner, State of art of natural inhibitors of calcium carbonate scaling, Desalination, 356 (2015) 47–55.
  8. M.M. Jordan, E. Sorhaug, D. Marlow, Red vs. green scale inhibitors for extending squeeze life – a case study from the North sea, Norwegian sector – part II, SPE Production and Operations, 27 (2012) 404–413.
  9. K.D. Demadis, E. Neofotistou, E. Mavredaki, M. Tsikakis, E.-M. Sarigiannidou, S.D. Katarachia, Inorganic foulants in membrane systems: chemical control strategies and the contribution of “green chemistry”, Desalination, 179 (2005) 281–295.
  10. N.M. Kumar, K. Kanny, A novel biodegradable poly(hydroxybutanedioic acid-co-2-hydroxypropane-1,2,3-tricarboxylic acid) copolymer for water treatment applications, Open J. Organic Polym. Mater., 2 (2013) 53–58.
  11. Y. Gao, L. Fan, L. Ward, Z. Liu, Synthesis of polyaspartic acid derivative and evaluation of its corrosion and scale inhibition performance in seawater utilization, Desalination, 365 (2015) 220–226.
  12. L. Xinhua, W. Wenjing, T. Xinjia, D. Yunfei, Z. Xinqiang, S. Hong, Study of corrosion and scale inhibition of polyepoxysuccinic acid derivative, Asian J. Chem., 26 (2014) 7716–7720.
  13. H. Zhang, F. Wang, X. Jin, Y. Zhu, A botanical polysaccharide extracted from abandoned corn stalks: modification and evaluation of its scale inhibition and dispersion performance, Desalination, 326 (2013) 55–61.
  14. A. Benbaki, T. Bachir-Bey, Synthesis and characterization of maleic acid polymer for use as scale deposits inhibitors, J. Appl. Polym. Sci., 116 (2010) 3095–3102.
  15. Y. Liu, Y. Zhou, Q. Yao, J. Huang, G. Liu, H. Wang, K. Cao, Y. Chen, Y. Bu, W. Wu, W. Sun, Double-hydrophilic polyether antiscalant used as a crystal growth modifier of calcium scales in cooling-water systems, J. Appl. Polym. Sci., 131 (2014) 39792/1-39792/12.
  16. B. Zhang, J. Li, X. Lv, Y. Cui, Y. Xu, Synthesis of polyaspartic acid/2-amino-2-methyl-1,3-propanediol graft copolymer and evaluation of its scale inhibition and corrosion inhibition performance, Desal. Wat. Treat., 54 (2014) 1998–2004.
  17. M. Xue, G. Liu, Y. Zhou, H. Wang, J. Huang, Q. Yao, L. Ling, K. Cao, Y. Liu, Y. Bu, Y. Chen, W. Wu, W. Sun, Acrylic acidallylpolyethoxy carboxylate copolymer: an effective and environmentally friendly inhibitor for carbonate and sulphate scales in cooling water systems, Int. J. Green Energy, 12 (2015) 1151–1158.
  18. J. Huang, G. Liu, Y. Zhou, Q. Yao, Y. Yang, L. Ling, H. Wang, K. Cao, Y. Liu, P. Zhang, W. Wu, W. Sun,
    Acrylic acid– allylpolyethoxy carboxylate copolymer as an environmentally friendly calcium carbonate and iron(III) scale inhibitor, Clean Technol. Environ. Policy, 15 (2013) 677–685.
  19. P.G. Klepetsanis, P.G. Koutsoukos, Z. Amjad, Calcium Carbonate and Calcium Phosphate Scale Formation and Inhibition at Elevated Temperature, Z. Amjad, Ed., Advances in Crystal Growth Inhibition Technologies, Kluwer Academic Publishers, New York, Boston, Dordrecht, London, Moscow, 2002, pp.139–149.
  20. L.A. Perez, D.F. Zidovec, Scale Control by Using a New Non-Phosphorus, Environmentally Friendly Scale Inhibitor, Z. Amjad, Ed., Mineral Scale Formation and Inhibition, Springer Science+Business Media, New York, 1998, pp. 47–61.
  21. R.V. Davis, P.W. Carter, M.A. Kamrath, D.A. Jonson, P.E. Reed, The Use of Modern Methods in the Development of Calcium Carbonate Inhibitors for Cooling Water System, Z. Amjad, Ed., Mineral Scale Formation and Inhibition, Springer Science+Business Media, New York, 1998, pp. 33–46.
  22. K.D. Demadis, B. Yang, P.R. Young, D.L. Kouznetsov, D.G. Kelley, Rational Development of New Cooling Water Chemical Treatment Programs for Scale and Microbial Control, Z. Amjad, Ed., Advances in Crystal Growth Inhibition Technologies, Kluwver Academic Publishers, New York, Boston, Dordrecht, London, Moscow, 2002, pp. 215–234.
  23. M.M. Reddy, G.H. Nancollas, Calcite crystal growth inhibition by phosphonates, Desalination, 12 (1973) 61–73.
  24. NACE Standard TM0374-2007 (formerly TM0374-2001), Item No. 21208, Laboratory Screening Tests to Determine the Ability of Scale Inhibitors to Prevent the Precipitation of Calcium Sulfate and Calcium Carbonate from Solution (for Oil and Gas Production Systems), 2007.
  25. Ionic Strength Corrections for Stability Constants using Specific Interaction Theory (SIT) for Windows 9x, NT, 2000, and xp, L.D. Pettit, Academic Software, IUPAC, 2003. Available on the IUPAC site: www.iupac.org and www.acadsoft.co.uk
  26. L. Ling, Y. Zhou, J. Huang, Q. Yao, G. Liu, P. Zhang, W. Sun, W. Wu, Carboxylate-terminated double-hydrophilic block copolymer as an effective and environmental inhibitor in cooling water systems, Desalination, 304 (2012) 33–40.
  27. D. Liu, W. Dong, F. Li, F. Hui, J. Lédion, Comparative performance of polyepoxysuccinic acid and polyaspartic acid on scaling inhibition by static and rapid controlled precipitation methods, Desalination, 304 (2012) 1–10.
  28. Y. Tang, W. Yang, X. Yin, Y. Liu, P. Yin, J. Wang, Investigation of CaCO3 scale inhibition by PAA, ATMP and PEPEMP, Desalination, 228 (2008) 55–60.
  29. Y. Xu, B. Zhang, L. Zhao, Y. Ciu, Synthesis of polyaspartic acid/5-aminoorotic acid graft copolymer and evaluation of its scale inhibition and corrosion performance, Desalination, 311 (2013) 156–161.
  30. C. Fu, Y. Zhou, G. Liu, J. Huang, W. Sun, W. Wu, Inhibition of Ca3(PO4)2, CaCO3 and CaSO4 precipitation for industrial recycling water, Ind. Eng. Chem. Res., 50 (2011) 10393– 10399.
  31. S.P. Gopi, V.K. Subramanian, Polymorphism in CaCO3 – effect of temperature under the influence of EDTA (di sodium salt), Desalination, 207 (2012) 38–47.
  32. P. Kjellin, X-ray diffraction and scanning electron microscopy studies of calcium carbonate deposited on a steel surface, Colloids Surf., A, 212 (2003) 19–26.
  33. G. Wolf, E. Königsberger, H.G. Schmidt, I.-C. Königsberger, H. Gamsjäger, Thermodynamic aspects of the vaterite-calcite phase transition, J. Therm. Anal. Calorim., 60 (2000) 463–472.
  34. K. Sawada, The mechanism of crystallization and transformation of calcium carbonates, Pure Appl. Chem., 69 (1997) 921–928.
  35. L. Liu, A. He, Research progress of scale inhibition mechanism, Adv. Mater. Res., 955–959 (2014) 2411–2414.
  36. D.S. Kim, K.C. Lee, Surface modification of precipitated calcium carbonate using aqueous fluorsilicic acid, Appl. Surf. Sci., 202 (2002) 15–23.
  37. A.A. Al-Hamzah, C.P. East, W.O.S. Doherty, C.M. Fellows, Inhibition of homogeneous formation of calcium carbonate by poly(acrylic acid). The effect of molar mass and end-group functionality, Desalination, 338 (2014) 93–105.
  38. G. Zhang, J. Ge, M. Sun, B. Sun, B. Pan, T. Mao, Z. Song, Investigation of scale inhibition mechanisms based on the effect of scale inhibitor on calcium carbonate crystal forms, Sci. China B., 50 (2007) 114–120.
  39. J. Loiseau, N. Doërr, J.M. Suau, J.B. Egraz, M.F. Llauro, C. Ladaviere, Synthesis and characterization of poly(acrylic acid) produced by RAFT polymerization. Application as a very efficient dispersant of CaCO3, kaolin, and TiO2, Macromolecules, 36 (2003) 3066–3077.
  40. R. Greenwood, Review of the measurement of zeta potentials in concentrated aqueous suspensions using electroacoustics, Adv. Colloid Interface Sci., 106 (2003) 55–81.
  41. W. Li, G. Zhang, J. Ge, P. Liu, Effects of phosphonates on zeta potential of calcium carbonate, Jingxi Shiyou Huagong Jinzhan, 6 (2005) 18–20; cited by Chem. Abstr.