Synthesis, Characterization, and Adsorptive Performance of Ag-Doped ZnO Nanoparticles for Melanoidin Removal

Authors

  • Mehwish Qaseem Department of Chemical Engineering, University of Karachi, Karachi, Pakistan
  • Saeed Ahmad Department of Chemical Skills, Yanbu Technical Institute, Yanbu, Saudi Arabia
  • Muhammad Yasir Khan Department of Chemical Engineering, University of Karachi, Karachi, Pakistan
  • Muhammad Wasim Akhtar Department of Metallurgy & Material Engineering, Mehran University of Engineering &Technology, Jamshoro, Sindh, Pakistan
  • Muhammad Furqan Ali Department of Chemical Engineering, University of Karachi, Karachi, Pakistan
  • Muhammad Saquib Ali Department of Chemical Engineering, University of Karachi, Karachi, Pakistan
  • Shakeel Ahmed Department of Chemical Engineering, University of Karachi, Karachi, Pakistan
  • Shahid Bhutto Centre of Environmental Studies, Pakistan Council of Scientific & Industrial Research (PCSIR), Karachi Complex, Karachi, Pakistan
  • Mehwish Altaf Department of Chemical Engineering, University of Karachi, Karachi, Pakistan

DOI:

https://doi.org/10.53560/PPASA(62-3)702

Keywords:

Melanoidin, Silver-doped Zinc Oxide, Adsorption, Nanoparticles, Wastewater Treatment, Kinetic Modelling

Abstract

Melanoidin, a complex polymer compound formed through Maillard reactions during fermentation, constitutes a significant fraction of distillery wastewater and cannot be treated using standard treatment methods. Silver doped zinc oxide nanoparticles (AgZnONPs) were synthesized, characterized, and used in this work as potential adsorbent to remediate melanoidin from aqueous solutions. The as-synthesized nanoparticles were evaluated using X-ray diffraction (XRD), UV-visible spectroscopy, field-emission scanning electron microscopy (FE-SEM) with energy-dispersive X-ray spectroscopy (EDX), and Fourier-transform infrared spectroscopy (FTIR). Adsorption experiments were performed under varying operational parameters, including solution pH, mass of adsorbent, initial melanoidin concentration, and time of contact. Under optimal conditions, pH 7, 0.5 g/L adsorbent, 200 mg/L of adsorbate concentration, and 90 min contact duration, a maximum removal efficiency of 92% was achieved. The enhanced adsorption performance aligns with the Langmuir isotherm approach, demonstrating monolayer adsorption with a 50 mg/g maximum adsorption capacity.  It adheres to pseudo-second-order kinetics, providing strong evidence of chemisorption with a rate-limiting mechanism and predominant process. These results illustrate the potential of AgZnONPs as a robust and efficient adsorbent material for the treatment of melanoidin-rich distillery effluents.

References

1. J.C.-T. Lin, Y.-S. Liu, and W.-K. Wang. A full-scale study of high-rate anaerobic bioreactors for whiskey distillery wastewater treatment with size fractionation and metagenomic analysis of granular sludge. Bioresource Technology 306: 123032 (2020).

2. B. Hu, L. Li, Y. Hu, D. Zhao, Y. Li, M. Yang, A. Jia, S. Chen, B. Li, and X. Zhang. Development of a novel Maillard reaction-based time-temperature indicator for monitoring the fluorescent AGE content in reheated foods. RSC Advances 10(18): 10402-10411 (2020).

3. M. Murata. Browning and pigmentation in food through the Maillard reaction. Glycoconjugate Journal 38(3): 283-294 (2021).

4. S. Tripathi, K. Singh, A.K. Singh, A. Mishra, and R. Chandra. Organo-metallic pollutants of distillery effluent and their toxicity on freshwater fish and germinating Zea mays seeds. International Journal of Environmental Science and Technology 19(3): 2021-2036 (2022).

5. M.S.I. Afrad, M.B. Monir, M.E. Haque, A.A. Barau, and M.M. Haque. Impact of industrial effluent on water, soil and rice production in Bangladesh: A case of Turag River bank. Journal of Environmental Health Science and Engineering 18(2): 825-836 (2020).

6. S. Ratna, S. Rastogi, and R. Kumar. Current trends for distillery wastewater management and its emerging applications for sustainable environment. Journal of Environmental Management 290: 112544 (2021).

7. R. Patel, R. Gaur, T. Verma, and R. Singh. Challenges of distillery effluent treatment and its bioremediation using microorganism: A review. Current World Environment 18(2): 446-459 (2023).

8. L.-N. Ho, S.-A. Ong, S.-H. Thor, and K.-L. Yap. Feasibility of UVA photocatalytic post-treatment of molasses wastewater: Effects on melanoidins removal, mineralization and oxidation of ammoniacal-nitrogen. Chemical Engineering and Processing: Process Intensification 196: 109681 (2024).

9. M. Binazadeh, J. Rasouli, S. Sabbaghi, S.M. Mousavi, S.A. Hashemi, and C.W. Lai. An overview of photocatalytic membrane degradation development. Materials 16(9): 3526 (2023).

10. Y. Li, Q. Zhang, S. Xiao, Q. Yang, L. Wang, and J. Hao. Review of melanoidins as by-product from thermal hydrolysis of sludge: Properties, hazards, and removal. Processes 12(1): 135 (2024).

11. L. Kheddo, L. Rhyman, M.I. Elzagheid, P. Jeetah, and P. Ramasami. Adsorption of synthetic dyed wastewater using activated carbon from rice husk. SN Applied Sciences 2(12): 2170 (2020).

12. J. Naser, Z. Ahmed, and E. Ali. Nanomaterials usage as adsorbents for the pollutants removal from wastewater: A review. Materials Today: Proceedings 42(5): 2590-2596 (2021).

13. V.S. Kadam, S.S. Wagh, C.V. Jagtap, S.M. Sutar, and R. Mane. Comparative studies on synthesis and photocatalytic activity of ZnO nanoparticles. ACS Omega 8(9): 7779-7790 (2023).

14. A. Abdelfattah and A. El-Shamy. A comparative study for optimizing photocatalytic activity of TiO₂-based composites with ZrO₂, ZnO, Ta₂O₅, SnO, Fe₂O₃, and CuO additives. Scientific Reports 14(1): 1 (2024).

15. U. Alalawi, U. Romman, K.M. Saleh, S.T. Shafa, and M.U. Khalid. Ag-doped MnO₂ nanowires integrated with graphitic carbon nitride for enhanced photocatalytic applications for wastewater treatment. Current Applied Physics 60: 32-39 (2024).

16. W. Xie, B. Li, X. Wu, D. Han, and Y. Zhang. Surface modification of ZnO with Ag improves its photocatalytic efficiency and photostability. Journal of Photochemistry and Photobiology A: Chemistry 215: 53-58 (2010).

17. S.K. Noukelag, L.C. Razanamahandry, S.K.O. Ntwampe, C.J. Arendse, and M. Maaza. Industrial dye removal using bio-synthesized Ag-doped ZnO nanoparticles. Environmental Nanotechnology, Monitoring & Management 16: 100463 (2021).

18. M. Nandasana, R. Kamat, R. Mishra, P. Ghosh, and S. Patil. Green synthesis of silver and copper-doped zinc oxide nanoflowers for photocatalytic and antibacterial applications. Vacuum 212: 111130 (2025).

19. S. Nagasundari, K. Muthu, K. Kaviyarasu, A. Farraj, and R.M. Alkufeidy. Current trends of silver-doped zinc oxide nanowires photocatalytic degradation for energy and environmental application. Journal of Environmental Chemical Engineering 23: 100931 (2021).

20. K. Watcharenwong, A. Kongka, C. Kaeokan, C. Chokejaroenrat, and C. Sakulthaew. Decolorization of melanoidin using sonoFenton and photoFenton processes. Waste 1(2): 455-467 (2023).

21. K. Brudzynski and D. Miotto. The recognition of high molecular weight melanoidins as the main components responsible for radical-scavenging capacity of unheated and heat-treated Canadian honeys. Food Chemistry 125(2): 570-575 (2011).

22. A.L. Jembere and M.B. Genet. Comparative adsorptive performance of adsorbents developed from sugar industrial wastes for the removal of melanoidin pigment from molasses distillery spent wash. Water Resources and Industry 26: 100165 (2021).

23. E.D. Revellame, D.L.B. Fortela, W. Sharp, R. Hernandez, and M.E. Zappi. Adsorption kinetic modeling using pseudo-first order and pseudo-second order rate laws: A review. Cleaner Engineering and Technology 1: 100032 (2020).

24. M.H. Rahman, M. Marufuzzaman, M.A. Rahman, and M.I.H. Mondal. Adsorption kinetics and mechanisms of nano chitosan coated cotton fiber for the removal of heavy metals from industrial effluents. Heliyon 11(1): e42932 (2025).

25. J.H. Mahamud, A.B. Gemta, A.K. Hordofa, G.A. Argaw, U. Sherefedin, M. Ahmed, T.F. Hurrisa, and T. Gurumurthi. Green synthesis and characterization of silver-doped ZnO nanoparticles using tobacco leaf extract: A novel hydrothermal approach for antibacterial and antifungal applications. AIP Advances 15(4): 045030 (2025).

26. S. Hussain, A. Fiaz, A. Almohammedi, and A. Waqar. Optimizing photocatalytic performance with Ag-doped ZnO nanoparticles: Synthesis and characterization. Heliyon 10(15): e35725 (2024).

27. O.A. Zelekew, S.G. Aragaw, F.K. Sabir, D.M. Andoshe, A.D. Duma, D.-H. Kuo, X. Chen, T.D. Desissa, B.B. Tesfamariam, G.B. Feyisa, H. Abdullah, E.T. Bekele, and F.G. Aga. Green synthesis of Co-doped ZnO via the accumulation of cobalt ion onto Eichhornia crassipes plant tissue and the photocatalytic degradation efficiency under visible light. Materials Research Express 8(2): 025010 (2021).

28. K. Raza, A. Sayeed, M. Naaz, M. Muaz, S. Rahaman, F. Sama, K. Pandey, and A. Ahmad. Green synthesis of ZnO nanoparticles and Ag-doped ZnO nanocomposite utilizing Sansevieria trifasciata for high-performance asymmetric supercapacitors. ACS Omega 9(30): 32444-32458 (2024).

29. M. Karimi-Nazarabad and E. Goharshadi. Ag and Ni doped graphitic carbon nitride coated on wood as a highly porous and efficient photo absorber in interfacial solar steam generation. Journal of Porous Materials 30(6): 1835-1845 (2023).

30. R. Radičić, D. Maletić, D. Blažeka, J. Car, and N. Krstulović. Synthesis of silver, gold, and platinum doped zinc oxide nanoparticles by pulsed laser ablation in water. Nanomaterials 12(19): 3484 (2022).

31. Z.N. Kayani, F. Manzoor, A. Zafar, M. Mahmood, M. Rasheed, and M. Anwar. Impact of Ag doping on structural, optical, morphological, and photoluminescent properties of ZnO nanoparticles. Optical and Quantum Electronics 52(7): 344 (2020).

32. M.B. Islam, M.J. Haque, N.M. Shehab, and M.S. Rahman. Synthesis and characterization (optical and antibacterial) of Ag-doped ZnO nanoparticles. Open Ceramics 14: 100370 (2023).

33. N. Ahmed, Z. Khalil, Z. Farooq, K.-U. Haq, S. Shahid, R. Ramiza, P. Ahmad, K.W. Qadir, R. Khan, and Q. Zafar. Structural, optical, and magnetic properties of pure and NiFe-codoped zinc oxide nanoparticles synthesized by a sol-gel autocombustion method. ACS Omega 9(1): 137-148 (2023).

34. N. Sedky, A. Afify, A. Almohammedi, E.M.M. Ibrahim, and A.M. Ali. Structural, optical, photoluminescence and magnetic investigation of doped and co-doped ZnO nanoparticles. Optical and Quantum Electronics 55: 456 (2023).

35. M. Busilă, V. Mușat, P. Alexandru, C. Romanitan, O. Brîncoveanu, V. Tucurăneanu, I. Mihalache, A.-V. Iancu, and V. Dediu. Antibacterial and photocatalytic activity of ZnO/Au and ZnO/Ag nanocomposites. International Journal of Molecular Sciences 24(23): 16939 (2023).

36. T.M. Irine and A. Rathika. Synthesis of silver (Ag) doped zinc oxide nanoparticles as efficient photocatalytic activity for degradation of methylene blue dye. Journal of Advanced Scientific Research 13(2): 129-134 (2022).

37. M.A. Kareem, I. Bello, H. Shittu, and P. Sivaprakash. Synthesis, characterization, and photocatalytic application of silver doped zinc oxide nanoparticles. Cleaner Materials 3: 100041 (2022).

38. L. Ashwini, L. Saravanan, M. Sabari, M. Astalakshmi, and N. Kanagathara. Effect of Cu doping with varying pH on photocatalytic activity of ZnO nanoparticles for the removal of organic pollutants. Inorganic Chemistry Communications 155: 111137 (2023).

39. N. Medoiuni, C. Guillard, F. Dappozze, L. Khrouz, S. Parola, C. Colbeau-Justin, A.B.H. Amara, H.B. Rhaiem, N. Jaffrezic-Renault, and P. Namour. Impact of structural defects on the photocatalytic properties of ZnO. Journal of Hazardous Materials Advances 6: 100081 (2022).

40. K. Akpomie and J. Conradie. Synthesis, characterization, and regeneration of an inorganic-organic nanocomposite (ZnO@biomass) and its application in the capture of cationic dye. Scientific Reports 10(1): 14441 (2020).

41. S. Rizvi, A. Singh, and S.K. Gupta. A parametric study using Box-Behnken design for melanoidin removal via Cu-impregnated activated carbon prepared from waste leaves biomass. Applied Water Science 12(4): 81 (2022).

42. R. Syaifuddin, R. Wahdah, A. Abdullah, and A.R. Saidy. Sorption of phosphate onto surfactant-modified zeolite particles. International Journal of Sciences: Basic and Applied Research 61(1): 87-96 (2022).

43. L.Q. Vo, A.-T. Vu, T.D. Le, C.D. Huynh, and H.V. Tran. Fe₃O₄/graphene oxide/chitosan nanocomposite: A smart nanosorbent for lead(II) ion removal from contaminated water. ACS Omega 9(15): 17506-17517 (2024).

44. S. Singh, S. Nimse, D.E. Mathew, A. Dhimmar, H. Sahastrabudhe, A. Gajjar, V. Ghadge, P. Kumar, and P.B. Shinde. Microbial melanin: Recent advances in biosynthesis, extraction, characterization, and applications. Biotechnology Advances 53: 107773 (2021).

45. X. Huang, W. Ye, J. Zhuang, C. Hu, H. Dong, B. Lei, and Y. Liu. π-Conjugated structure enhances the UV absorption performance of carbon dots and application in the design of light-colored sunglasses. ACS Sustainable Chemistry & Engineering 12(28): 10399-10408 (2024).

46. M. Han, H. Zhao, Z. Liu, J. Liu, X. Li, F. Hang, K. Li, and C. Xie. Color development characteristic and kinetic modeling of Maillard reaction in membrane-clarified sugarcane juice during vacuum evaporation process. Foods 14(12): 2136 (2025).

47. B.-H. Fan, Y.-S. Xiong, M.-X. Li, R. Jia, L.-S. Zhou, J.-Y. Tang, W. Li, Y.-W. Lan, H.-Q. Lu, and K. Li. Effective melanoidin adsorption of polyethyleneimine-functionalised molasses-based porous carbon: Adsorption behaviours and microscopic mechanisms. Separation and Purification Technology 310: 123016 (2022).

48. I. Šarić and I. Despotović. Hydrogen bonds as stability-controlling elements of spherical aggregates of ZnO nanoparticles: A joint experimental and theoretical approach. Materials 16(13): 4843 (2023).

49. S.M. Rafigh and A.R. Soleymani. Melanoidin removal from molasses wastewater using graphene oxide nanosheets. Separation Science and Technology 55(13): 2281-2293 (2020).

50. R. Dolphen and P. Thiravetyan. Adsorption of melanoidins by chitin nanofibers. Chemical Engineering Journal 166(3): 890-895 (2011).

51. S. Rizvi, L. Goswami, and S.K. Gupta. A holistic approach for melanoidin removal via Fe-impregnated activated carbon prepared from Mangifera indica leaves biomass. Bioresource Technology Reports 12: 100591 (2020).

52. S. Ahmed, I.N. Unar, H.A. Khan, G. Maitlo, R.B. Mahar, A.S. Jatoi, A.Q. Memon, and A.K. Shah. Experimental study and dynamic simulation of melanoidin adsorption from distillery effluent. Environmental Science and Pollution Research 27: 9619-9636 (2020).

53. K. Suwannahong, S. Wongcharee, J. Rioyo, C. Sirilamduan, and T. Kreetachart. Insight into molecular weight cut-off characteristics and reduction of melanoidin using microporous and mesoporous adsorbent. Engineering and Applied Science Research 49(1): 47-57 (2021).

54. B.O. Otieno, S.O. Apollo, B.E. Naidoo, and A. Ochieng. Photodecolorisation of melanoidins in vinasse with illuminated TiO₂-ZnO/activated carbon composite. Journal of Environmental Science and Health, Part A 52(7): 616-623 (2017).

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Published

2025-09-24

How to Cite

Mehwish Qaseem, Saeed Ahmad, Muhammad Yasir Khan, Muhammad Wasim Akhtar, Muhammad Furqan Ali, Muhammad Saquib Ali, … Mehwish Altaf. (2025). Synthesis, Characterization, and Adsorptive Performance of Ag-Doped ZnO Nanoparticles for Melanoidin Removal. Proceedings of the Pakistan Academy of Sciences: A. Physical and Computational Sciences, 62(3), 235–246. https://doi.org/10.53560/PPASA(62-3)702

Issue

Vol. 62 No. 3 (2025)

Section

Research Articles

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