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In this study, a new adsorbent derived from sunflower husk powder and coated in CuO nanoparticles (CSFH) was investigated to evaluate the simultaneous adsorption of Levofloxacin (LEV), Meropenem (MER), and Tetracycline (TEC) from an aqueous solution. Significant improvements in the adsorption capacity of the sunflower husk were identified after the powder particles had been coated in CuO nanoparticles. Kinetic data were correlated using a pseudo-second-order model, and was successful for the three antibiotics. Moreover, high compatibility was identified between the LEV, MER, and TEC, isotherm data, and the Langmuir model, which produced a better fit to suit the isotherm curves. In addition, the spontaneous and exothermic nature of the adsorption process was crucial for transforming the three antibiotics into CSFH. The greatest CSFH adsorption capacity was in MER (131.83 mg/g), followed by TEC (96.95 mg/g), and LEV (62.24 mg/g). These findings thus indicate that CSFH is one of the most effective and efficient adsorbents to use for eliminating wastewater contaminated with antibiotic residue.
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30--42
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Bibliogr. 41 poz., rys., tab.
Twórcy
autor
- Department of Civil Enginering, College of Engineering, Al-Nahrain University, Baghdad, Iraq
autor
- Department of Civil Enginering, College of Engineering, Al-Nahrain University, Baghdad, Iraq
autor
- Reconstruction and Projects Directorate, Ministry of Higher Education and Scientific Research, Baghdad, Iraq
autor
- Department of Environmental Engineering, College of Engineering, University of Baghdad, Iraq
autor
- Department of Civil Enginering, College of Engineering, Al-Nahrain University, Baghdad, Iraq
autor
- Department of Chemical Engineering, College of Engineering, University of Baghdad, Iraq
- Department of Chemical Engineering, Faculty of Engineering, Universiti Malaya, Kuala Lumpur, Malaysia
autor
- Department of Environmental Engineering, College of Engineering, University of Baghdad, Iraq
autor
- Department of Chemical and Process Engineering, Faculty of Engineering and Built Environment, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
autor
- Department of Chemical and Process Engineering, Faculty of Engineering and Built Environment, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
- Research Centre for Sustainable Process Technology (CESPRO), Faculty of Engineering and Built Environment, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia
Bibliografia
- 1. Abed K.M. 2014. Kinetic of Alkaloids Extraction from Plant by Batch Pertraction in Rotating Discs Contactor. Iraqi Journal of Chemical and Petroleum Engineering, 15(2), 75–84.
- 2. Abed K.M. 2015. Separation of alkaloids from plants by bulk liquid membrane technique using rotating discs contactor: Chemical. Diyala Journal of Engineering Sciences, 8(4), 785–793.
- 3. Ahmed M.J., Theydan S.K. 2013. Microwave assisted preparation of microporous activated carbon from Siris seed pods for adsorption of metronidazole antibiotic. Chemical Engineering Journal, 214, 310–318.
- 4. Al-Jabari M.H., Sulaiman S., Ali S., Barakat R., Mubarak A., Khan S.A. 2019. Adsorption study of levofloxacin on reusable magnetic nanoparticles: Kinetics and antibacterial activity. Journal of Molecular liquids, 291, 111249.
- 5. Aljeboree A.M., Alshirifi A.N., Alkaim A.F. 2017. Kinetics and equilibrium study for the adsorption of textile dyes on coconut shell activated carbon. Arabian Journal of Chemistry, 10, S3381–S3393.
- 6. Al-Hemiri A.A., Abed K.M., Al-Shahwany A. W. 2012. Extraction of Pelletierine from Punica granatum L. by Liquid Membrane Technique and Modelling. Iraqi Journal of Chemical and Petroleum Engineering, 13(1), 1–9.
- 7. Attia T.M.S., Hu X.L., Qiang Y.D. 2013. Synthesized magnetic nanoparticles coated zeolite for the adsorption of pharmaceutical compounds from aqueous solution using batch and column studies. Chemosphere, 93(9), 2076–2085.
- 8. Boparai H.K., Joseph M., O’Carroll D.M. 2011. Carroll Kinetics and thermodynamics of cadmium ion removal by adsorption onto nanozerovalent iron particles. Journal of Hazardous Materials, 186(1), 458–465.
- 9. Chen, H., Gao, B., Li, H., 2015. Removal of sulfamethoxazole and ciprofloxacin from aqueous solutions by graphene oxide. Journal of Hazardous Materials, 283, 201–207.
- 10. Danalıoğlu S.T., Bayazit Ş.S., Kuyumcu Ö.K., Abdel Salam M. 2017. Efficient removal of antibiotics by a novel magnetic adsorbent: Magnetic activated carbon/chitosan (MACC) nanocomposite. Journal of Molecular Liquids, 240, 589–596.
- 11. Dostert K-H., O›Brien C.P., Mirabella F., IvarsBarceló F., Schauermann S. 2016. Adsorption of acrolein, propanal, and allyl alcohol on Pd(111): a combined infrared reflection–absorption spectroscopy and temperature programmed desorption study. Journal of Physical Chemistry Chemical Physics, 18, 13960–13973.
- 12. Elragehy N.A., Abdel-Moety E. M., Hassan N.Y., Rezk M.R. 2008. Stability-indicating determination of meropenem in presence of its degradation product. Talanta, 77(1), 28–36.
- 13. Ersan M., Guler U.A., Acıkel U., Sarioglu M. 2015. Synthesis of hydroxyapatite/clay and hydroxyapatite/pumice composites for tetracycline removal from aqueous solutions. Process Safety and Environmental Protection, 96, 22–32.
- 14. Figueroa R.A., Leonard A., Mackay A.A. 2004. Modeling tetracycline antibiotic sorption to clays. Environmental Science and Technology, 38(2), 476–483.
- 15. Fukahori S., Fujiwara T. 2014. Modeling of sulfonamide antibiotic removal by TiO2/high-silica zeolite HSZ-385 composite. Journal of Hazardous Materials, 272, 1–9.
- 16. Gupta, V.K., Agarwal S., Asif M., Fakhri A., Sadeghi N. 2017. Application of response surface methdology to optimize the adsorption performance of a magnetic graphene oxide nanocomposite adsorbent for removal of methadone from the environment. Journal of Colloid Interface Science, 497, 193–200.
- 17. Gupta V.K., Saleh T.A. 2013. Sorption of pollutants by porous carbon, carbon nanotubes and fullerenean overview. Environmental Science and Pollution Research, 20, 2828–2843.
- 18. Inyang M., Gao B., Zimmerman A., Zhang M., Chen H., 2014. Synthesis, characterization, and dye sorption ability of carbon nanotube-biochar nano composites. Chemical Engineering Journal, 236, 39–46.
- 19. Mahmoud M.E., El-Ghanam A.M., Mohamed R.H.A., Saad S.R. 2020. Enhanced adsorption of Levofloxacin and Ceftriaxone antibiotics from water by assembled composite of nanotitanium oxide/chitosan/nano-bentonite. Materials Science and Engineering, C, 108, 110199.
- 20. Michael I., Rizzo L., McArdell C.S., Manaia C.M., Merlin C., Schwartz T., Dagot C., Fatta-Kassinos D. 2013. Urban wastewater treatment plants as hotspots for the release of antibiotics in the environment: A review. Water Research, 47(3), 957–995.
- 21. Mohammed A.A., Al-Musawi T.J., Kareem S.L. Zarrabi M., Alaa M., Al-Ma’abreh M.A. 2020. Simultaneous adsorption of tetracycline, amoxicillin, and ciprofloxacin by pistachio shell powder coated with zinc oxide nanoparticles. Arabian Journal of Chemistry, 13, 4629–4643.
- 22. Mohammed S.J., M-Ridha M.J., Abed K.M., Elgharbawy A.A. 2021. Removal of levofloxacin and ciprofloxacin from aqueous solutions and an economic evaluation using the electrocoagulation process. International Journal of Environmental Analytical Chemistry, 1–19.
- 23. Mohammed S.J., Mohammed-Ridha M.J. 2021. Optimization of levofloxacin removal from aqueous solution using electrocoagulation process by response surface methodology. Iraqi Journal of Agricultural Sciences, 52(1), 204–217.
- 24. Mohseni-Bandpi A., Al-Musawi T.J., Ghahramani E., Zarrabi M., Mohebi S., Vahed S.A. 2016. Improvement of zeolite adsorption capacity for cephalexin by coating with magnetic Fe3O4 nanoparticles. Journal of Molecular Liquids, 218, 615–624.
- 25. M-Ridha M.J., Hasan Y.R., Ibrahim M.A. 2020. Adsorption kinetics and mechanisms for meropenem antibiotic removal in batch mode via rice husk functionalized with Mg/Fe-layered double hydroxides. Separation Science and Technology, 56(16), 2721–2733.
- 26. Pouretedal H.R., Sadegh N. 2014. Effective removal of Amoxicillin, Cephalexin, Tetracycline and Penicillin G from aqueous solutions using activated carbon nanoparticles prepared from vine wood. Journal of Water Process Engineering, 1, 64–73.
- 27. Ramani R.V., Ramani B.M., Saparia A.D., Dhruv D., Markna J.H. 2015. Synthesis and optical characterization of CuO nanoparticles on solar borosilicate glass. Journal of Nano Research, 37, 68–73.
- 28. Shaban M.A.A., Ibrahim M.A., M-Ridha M.J., Haitham A. Hussein H.A. 2020. Adsorption of meropenem antibiotics from aqueous solutions on multi-walled carbon nanotube, performance, mechanism, and modeling. International Review of Civil Engineering (I.RE.C.E.), 11(6), 283–293.
- 29. Shi L., Zhang X., Chen Z. 2011. Removal of chromium (VI) from wastewater using bentonite-supported nanoscale zero-valent iron. Water Research, 45(2), 886–892.
- 30. Song G., Guoa Y., Lia G., Zhaoc W., Yud Y. 2019. Comparison for adsorption of tetracycline and cefradine using biochar derived from seaweed Sargassum sp. Desalination and Water Treatment, 160, 316–324.
- 31. Soori M.M., Ghahramani E., Kazemian H., AlMusawi T.J., Zarrabi M. 2016. Intercalation of tetracycline in nano sheet layered double hydroxide: an insight into UV/VIS spectra analysis. Journal of the Taiwan Institute of Chemical Engineers, 63, 271–285.
- 32. Sun Y., Li H., Li G., Gao B., Yue Q., Li X. 2016. Characterization and ciprofloxacin adsorption properties of activated carbons prepared from biomass wastes by H3PO4 activation. Bioresource Technology, 217, 239–244.
- 33. Teixeira S., Delerue-Matos C., Santos L. 2019. Application of experimental design methodology to optimize antibiotics removal by walnut shell based activated carbon. Science of the Total Environment, 646, 168–176.
- 34. Ternes T.A, Joss A., Siegrist H. 2004. Scrutinizing pharmaceuticals and personal care products in wastewater treatment. Environmental Science and Technology, 38(20), 392A–399A.
- 35. Tian Y., Gao B., Chen H., Wang Y., Li H. 2013a. Interactions between carbon nanotubes and sulfonamide antibiotics in aqueous solutions under various physicochemical conditions. Journal of Environmental Science and Health, 48(9), 1136–1144.
- 36. Tian Y., Gao B., Morales V.L., Chen H., Wang Y., Li H. 2013b. Removal of sulfa methoxazole and sulfapyridine by carbon nanotubes in fixed-bed columns. Chemosphere, 90(10), 2597–2605.
- 37. Wang J., Gao B., Dou M., Huang X., Ma Z. 2020. A porous g-C3N4 nanosheets containing nitrogen defects for enhanced photocatalytic removal meropenem: Mechanism, degradation pathway and DFT calculation. Environmental Research, 184, 109339.
- 38. Wu Q., Li Z., Hong H., Yin K., Tie L. 2010. Adsorption and intercalation of ciprofloxacin on montmorillonite. Applied Clay Science, 50(2), 204–2011.
- 39. Yang W., Lu Y., Zheng F., Xue X., Li N., Liu, D. 2012. Adsorption behavior and mechanisms of norfloxacin onto porous resins and carbon nanotube. Chemical Engineering Journal, 179, 112–118.
- 40. Yetilmezsoy K., Demirel S. 2008. Artificial neural network (ANN) approach for modeling of Pb(II) adsorption from aqueous solution by Antep pistachio (Pistacia Vera L.) shells. Journal of Hazardous Materials, 153, 1288–1300.
- 41. Yi S., Gao B., Sun Y., Wu J., Shi X., Wu B. 2015. Removal of levofloxacin from aqueous solution using rice-husk and wood-chip biochars. Chemosphere, 150, 694–701.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-3906ee47-7bbd-4207-a2cf-385afcae26ea