Investigation of Adsorptive Removal of Methylene Blue from Synthetic Wastewater Using Polymeric Composite

Year 2023, , 961 - 974, 11.11.2023

Monsuru Dauda Ayobami Ajani Tınuade Jolaade Afolabı Abass Alade

https://doi.org/10.18596/jotcsa.1148910

Cited By: 1

Abstract

Recycling polymeric waste into another useful material is considered to be the preferred way of taking care of the issues of slow degradable plastic waste, particularly in anticipation of natural contamination. In this study, the adsorptive treatment of Methylene Blue (MB) using adsorbents from chemically recycled polymeric waste was investigated. Three polymeric materials were employed in this study: styrofoam waste (EPS1), intruded extended polystyrene (EPS2), and sunflower xylem (Tithonia diversifolia xylem) (TDX). The alterations in microscopic surface morphology before and after the adsorption process were examined using scanning electron microscopy (SEM) system to resolve the intercalation of MB with the adsorbent. The experimental batch data was collected and the effects of concentration and contact time on the removal of MB from synthetic wastewater were studied. Adsorption kinetics, equilibrium, and thermodynamics were studied and fitted by various models. According to the result, the uptake of adsorbate increased as contact time and concentration rose, with the pseudo-second-order model best depicting the adsorption kinetics.

Keywords

Adsorbent Composite, Methylene Blue, Polymeric Adsorbents

References

• 1. Bekri-Abbes I, Bayoudh S, Baklouti M. Converting Waste Polystyrene into Adsorbent: Potential Use in the Removal of Lead and Cadmium Ions from Aqueous Solution. . Journal of Polymers and the Environment. 2006;14(3):249–56.
• 2. Bingjun Pan BP, Weiming Zhang, Lu Lv, Quanxing Zhang, Shourong Zheng. Development of polymeric and polymer-based hybrid adsorbents for pollutants removal from waters. Chemical Engineering Journal. 2009:151 (2009) 19–29.
• 3. Parashar N, Hait S. Plastics in the time of COVID-19 pandemic: Protector or polluter. Sci Total Environ 2021:759, 144274.
• 4. Santoso E, Ediati R, Kusumawati Y, Bahruji H, Sulistiono DO, Prasetyoko D. Review on recent advances of carbon-based adsorbent for methylene blue removal from wastewater. Materials Today Chemistry. 2020:16.
• 5. Abdoulaye DNd, Youssef AEHA, Mohamed AB, Mostafa S, Mohamed SAK, Driss F. Adsorption of Methylene Blue from aqueous solution using Senegal River Typha australis. Mediterranean Journal of Chemistry. 2020;10(1):22-32.
• 6. Jiyun S, Weihua Z, Yangyang B, Fengyun S, Runping H. Adsorption characteristics of methylene blue by peanut husk in batch and column modes. Desalination. 2011;265(1-3):13.
• 7. Alade AO, Amuda OS, Afolabi TJ, Okoya AA. Adsorption of Naphthalene onto Activated Carbons Derived from milk bush shell and flamboyant pod. Journal of Environmental Chemistry and Ecotoxicology. 2012:4, 124-32.
• 8. Mingliang G, Wang X, Mingyi D, Liang G, Guoqing H, Jahangir A. Adsorption Analyses of Phenol from Aqueous Solutions Using Magadiite Modified with Organo-Functional Groups: Kinetic and Equilibrium Studies. Material. 2019:1-16.
• 9. Langmuir I. he constitution and fundamental properties of solids and liquids. J Am Chem Soc. 1916:38, 2221–95.
• 10. Emmanuel UI, Martins OO, Nurudeen OA. Modeling In Adsorption: Fundamentals And Applications. Composite Nanoadsorbents: Elseviers; 2019. p. 85-118.
• 11. Hall KR, Egleton LC, Acrivos A, Vemeulen T. Pore and solid diffusion kinetics in fixed bed adsorption under constant pattern conditions. Industrial and Engineering Chemistry Fundamentals. 1966:52 12-223.
• 12. Mohammad SA, Rexona K, Mohammad AR. Removal of Congo Red Dye from Industrial Wastewater by Untreated Sawdust. American Journal of Environmental Protection. 2015;4(5):207-13.
• 13. Freundlich HMF. Über die adsorption in lösungen. . Z Phys Chem 1906:57, 385–470.
• 14. Hutson ND, Yang RT. Theoretical basis for the Dubinin-Radushkevitch (D-R) adsorption isotherm equation. Adsorption 1997;3(3):189–95.
• 15. Li YH, Wang S, Luan Z, Ding J, Xu C, Wu D. Adsorption of Cadmium( II) from aqueous solution by surface oxidized carbon nanotubes. 2003:1057–62.
• 16. Dada AO, Latona DF, Ojediran OJ, Osazuwa ON. Adsorption of Cu (II) onto Bamboo Supported Manganese (BS-Mn) Nanocomposite: Effect of Operational Parameters, Kinetic, Isotherms, and Thermodynamic Studies. Journal of Applied Sciences and Environmental Management. 2016:20(2), 409 –22.
• 17. Mohammed K, Noor A, Hayder A, Al-Furaji M. Removal of dyes by agricultural waste. Sustainable Chemistry and Pharmacy. 2020;16:1-9.
• 18. Sahoo TR, Priyadarshini B, Rath PP, Behera SS, Panda RS, Parhi PK. Kinetics, Thermodynamics and Isotherm Studies on Adsorption of IOP Conference Series: Materials Science and Engineering. 2018:31(5), 1-13.
• 19. Ali B, Kamel R. Improvement adsorption capacity of methylene blue onto modified Tamazert kaolin. Adsorption Science & Technology. 2017;35(9–10):753–73.
• 20. Babalola BM, Adegoke OB, Akintayo CO, Lawal OS, Abimbade SF, Oseghe EO. Adsorption and desorption studies of Delonix regia pods and leaves: removal and recovery of Ni(II) and Cu(II) ions from aqueous solution. Drinking Water Engineering Science. 2020:13(4), 5-27.
• 21. Pandimadevi MA, Rajalekshmi GA, Mrithaa TS, Viji-Chandran SA. Preparation and Characterisation of Activated Carbon from Delonix regia Seeds for the Removal of Methylene Blue Dye. Journal of Industrial Pollution Control. 2016;32(2):572-9.
• 22. Dehghani MH, Tajik S, Panahi A, Khezri M, Zarei A, Heidarinejad Z, et al. Adsorptive removal of noxious cadmium from aqueous solutions using poly urea-formaldehyde: A novel polymer adsorbent. Methods. 2018:1148–55.
• 23. Amole AR, Araromi DO, Alade AO, Afolabi TJ, Adeyi VA. Biosorptive removal of nitrophenol from aqueous solution using ZnCl2-modified groundnut shell: optimization, equilibrium, kinetic, and thermodynamic studies. International Journal of Environmental Science and Technology. 2021:1859-76.