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Issue
Korean Journal of Chemical Engineering,
Vol.39, No.3, 616-627, 2022
Fabrication of modified nanofiltration membranes by functionalizedcellulose nanocrystals with high anti-fouling capability in removing dye from water and wastewater
Amiri M, Jafarbeigi E, Salimi F
The aim of this study was to remove Azo dye, Direct Red 16, from a synthetic solution, 50 mg/l, and also to treat the wastewater of the licorice extract plant, LEP, by nanofiltration membrane with high anti-fouling properties. In this regard, a new polymer nanocomposite was fabricated by mixing cellulose nanocrystals functionalized with amino acid cysteine (CNF-AAC) and investigating the effective parameters such as anti-fouling properties, as well as the performance of the modified membrane in removing the dye. In this regard, field emission scanning electron microscopy (FESEM), scanning-force microscopy (SFM), atomic force microscopy (AFM) and contact angle measurements were performed. The results of AFM analysis indicated that the surface roughness of polyether sulfone-membrane is reduced by the addition of CNF-AAC. Therefore, by increasing the concentration of nanocrystals from 0 to 1 wt% in the initial solution of the membrane, the net distilled water flux permeation has increased from 18.05 (kg/m2h) to 26.50 (kg/m2h). Also, with increasing the concentration of CNF-AAC in the initial solution of the membranes, the size of the contact angle has gradually decreased. Meanwhile, adding a small amount of CNF-AAC (0.5 wt%) to the polyether-sulfone membrane has led to reducing the rate of irreversible fouling from 43.34% to 4.89% and in contrast, to increasing the amount of reversible fouling from 30.02% to 63.54%. On the other hand, in this study, the yield of dye solution by the optimal membrane is 98.38%, for which the percentage of COD removal for the wastewater of LEP has reached 90%.
Keywords: Nanofiltration; Licorice Extract Factory Wastewater; Cellulose Nanocrystals Functionalized with the AminoAcid Cysteine; Polyether-sulfone; Direct Red 16
[References]
  1. Hoseini SN, Pirzaman AK, Aroon MA, Pirbazari AE, J. Water Process Eng., 17, 124, 2017
  2. Chamjangali MA, Bagherian G, Javid A, Boroumand S, Farzaneh N, Spectrochim. Acta, Part A, 150, 230, 2015
  3. Zohra B, Aicha K, Fatima S, Nourredine B, Zoubir D, Chem. Eng. J., 136, 295, 2008
  4. Pandey A, Singh P, Iyengar L, International Biodeterioration & Biodegradation, 59, 73, 2007
  5. Malik P, Saha S, Sep. Purif. Technol., 31, 241, 2003
  6. Koch M, Yediler A, Lienert D, Insel G, Kettrup A, Chemosphere, 46, 109, 2002
  7. Panswad T, Wongchaisuwan S, Water Sci. Technol., 18, 139, 1986
  8. Kamari M, Shafiee S, Salimi F, Karami C, Desalin. Water Treat., 161, 304, 2019
  9. Salimi F, Rahimi H, Karami C, Desalin. Water Treat., 137, 334, 2019
  10. Busca G, Berardinelli S, Resini C, Arrighi L, J. Hazard. Mater., 160, 265, 2008
  11. Dunn RO Jr, Scamehorn JF, Christian SD, Sep. Sci. Technol., 20, 257, 1985
  12. Siemiatycki J, Richardson L, Straif K, Latreille B, Lakhani R, Campbell S, Rousseau MC, Boffetta P, Environ. Health Perspect., 112, 1447, 2004
  13. Conidi C, Fuc L, Drioli E, Cassano A, Molecules, 24, 2279, 2019
  14. Mukherjee R, De S, J. Hazard. Mater., 265, 8, 2014
  15. Mukherjee R, De S, Chem. Eng. J., 302, 773, 2016
  16. Baker RW, Membrane technology and applications, John Wiley & Sons (2012).
  17. Madaeni S, Sohrabi M, Khosravi M, Ghaedi A, Sep. Sci. Technol., 46, 1406, 2011
  18. Gorgol LJ, Taub SG, Olesiewicz J, U.S. Patent, US20110196 138A1 (2011).
  19. Jonoobi M, Ashori A, Siracusa V, Polymer Testing, 76, 333, 2019
  20. Rafieian F, Hosseini M, Jonoobi M, Yu Q, Cellulose, 25, 4695, 2018
  21. Norouzbahari S, Roostaazad R, Hesampour M, Desalination, 238, 174, 2009
  22. Abouzeid RE, Khiari R, El-Wakil N, Dufresne A, Biomacromolecules, 20, 573, 2018
  23. Rafieian F, Jonoobi M, Yu Q, Cellulose, 26, 3359, 2019
  24. Goetz LA, Naseri N, Nair SS, Karim Z, Mathew AP, Cellulose, 25, 3011, 2018
  25. Bai H, Wang X, Zhou Y, Zhang L, Prog. Nat. Sci. Mater. Int., 22, 250, 2012
  26. Jahan Z, Niazi MBK, Gregersen OW, J. Ind. Eng. Chem., 57, 113, 2018
  27. Zinadini S, Zinatizadeh AA, Rahimi M, Vatanpour V, Zangeneh H, J. Membr. Sci., 453, 292, 2014
  28. Bagheripour E, Moghadassi A, Hosseini S, Nemati M, J. Membr. Sci. Res., 2, 14, 2016
  29. Vatanpour V, Madaeni SS, Khataee AR, Salehi E, Zinadini S, Monfared HA, Desalination, 292, 19, 2012
  30. Cossee RP, Geus ER, Van EJ, U.S. Patent, 6,488,856 (2002).
  31. Hokkanen S, Bhatnagar A, Sillanpaa M, Water Res., 91, 156, 2016
  32. Koschevic MT, dos Santos M, de Faria RC, Fakhouri FM, Martelli SM, Chapter 9 - cellulose nanocrystals functionalization by grafting, Thakur VK, Ed., Biopolymer Grafting, Elsevier, 409 (2018).
  33. Sofla MRK, Brown R, Tsuzuki T, Rainey T, Adv. Nat. Sci. Nanosci. Nanotechnol., 7, 35004, 2016
  34. Cheng Q, Ye D, Chang C, Zhang L, J. Membr. Sci., 525, 1, 2017
  35. Zinadini S, Rostami S, Vatanpour V, Jalilian E, J. Membr. Sci., 529, 133, 2017
  36. Vatanpour V, Madaeni SS, Moradian R, Zinadini S, Astinchap B, J. Membr. Sci., 375, 284, 2011
  37. Celik E, Park H, Choi H, Choi H, Water Res., 45, 274, 2011
  38. Barzin J, Feng C, Khulbe KC, Matsuura T, Madaeni SS, Mirzadeh H, J. Membr. Sci., 237, 77, 2004
  39. Lv J, Zhang G, Zhang H, Zhao C, Yang F, Appl. Surf. Sci., 440, 1091, 2018
  40. Karim Z, Mathew AP, Grahn M, Mouzon J, Oksman K, Carbohydr. Polym., 112, 668, 2014
  41. Rahimi M, Dadari S, Zeinaddini S, Mohamadian E, Korean J. Chem. Eng., 34, 1444, 2017
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