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Biochar as a Cadmium Scavenger in the Aquatic Environment Remediation: Date Seeds as Raw Material

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
It was found that date seeds are suitable for biochar production due to their low moisture content 8.92%, low ash yield 1.05%, and high organic matter content 78.3%. The biochar was produced by pyrolysis at 350, 450 and 550°C. The effect of pyrolysis temperature on the physicochemical characteristics of biochar was investigated. It was found that the porosity, water holding capacity, ash content, pH, organic matter, fixed carbon, and the elemental content of Na, K, Ca, Mg, Fe, Mn, P, Zn, Ba, Cr, Cu, Ni, Pb, Ti, and V were increased along with pyrolysis temperature. Meanwhile, the biochar yield, bulk density, and the total content of N and S were decreased. The biochar was tested as a sustainable adsorbent to investigate the adsorption of Cd from contaminated water. The adsorption isotherms of Cd on biochar were determined based on Langmuir equation. The maximum adsorption of Cd at 25°C and pH 7 were 667, 714, and 833 mg/kg for the biochars produced at 350, 450, and 550°C, respectively. On the basis of the physicochemical characteristics of the biochar and the findings from Langmuir equation that showed the biochar produced at 550°C has the highest adsorption capacity for Cd, the desorption/adsorption experiment was carried out using the biochar produced at 550°C. The adsorption of Cd by biochar was directly proportional to the Cd concentrations. It was increased from 0.009 mmol/0.5g at 0.01 mmol Cd to 0.12 mmol/0.5g at 0.2 mmol Cd concentration. The desorption of Cd from biochar was increased proportionally to cadmium concentrations from 0.01 to 0.05 mmol and became constant above 0.05 mmol, regardless of the increment of cadmium concentrations. High retention potential for the cadmium that adsorbed within the biochar was proven in this study with desorption/adsorption percentage of 16%. These findings provide a successful example of date seeds converting into the sustainable adsorbent for Cd removal from aquatic environment to achieve the conception of eco-friendly production, which should be studied further.
Słowa kluczowe
Rocznik
Strony
270--280
Opis fizyczny
Bibliogr. 37 poz., rys., tab.
Twórcy
  • Prince Faisal Center for Dead Sea, Environmental and Energy Research, Mutah University, Karak, 61710, Jordan
Bibliografia
  • 1. Ahmad, T., Danish, M., Rafatullah, M., Ghazali, A., Sulaiman, O., Hashim, R., and Ibrahim, M. N. M. 2012. The use of date palm as a potential adsorbent for wastewater treatment: a review. Environmental Science and Pollution Research, 19(5), 1464-1484.
  • 2. Al-Wabel, M. I., Al-Omran, A., El-Naggar, A. H., Nadeem, M., & Usman, A. R. 2013. Pyrolysis temperature induced changes in characteristics and chemical composition of biochar produced from conocarpus wastes. Bioresource technology, 131, 374-379.
  • 3. Angın, D. (2013). Effect of pyrolysis temperature and heating rate on biochar obtained from pyrolysis of safflower seed press cake. Bioresource technology, 128, 593-597.
  • 4. Babu, A. T., Vijay, A. K., Bhanuvikraman, A. K., and Madhavan, A. 2021. A study on biochar Preparation and Characterization of Broiler’s Poultry Litter. International Journal of Ecology and Environmental Sciences, 47(3), 209-218.
  • 5. Banat, F., Al-Asheh, S., & Al-Makhadmeh, L. 2003. Kinetics and equilibrium study of cadmium ion sorption onto date pits—an agricultural waste. Adsorption Science and Technology, 21(3), 245-260.
  • 6. Bouchelta, C., Medjram, M. S., Bertrand, O., and Bellat, J. P. 2008. Preparation and characterization of activated carbon from date stones by physical activation with steam. Journal of Analytical and Applied Pyrolysis, 82(1), 70-77.
  • 7. Cheng, S., Liu, Y., Xing, B., Qin, X., Zhang, C., and Xia, H. 2021. Lead and cadmium clean removal from wastewater by sustainable biochar derived from poplar saw dust. Journal of Cleaner Production, 128074.
  • 8. De Gisi, S., Lofrano, G., Grassi, M., and Notarnicola, M. 2016. Characteristics and adsorption capacities of low-cost sorbents for wastewater treatment: A review. Sustainable Materials and Technologies, 9, 10-40.
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  • 10. El May, Y., 2012. Measurement of Gaseous and Particulate Pollutants during Combustion of Date Palm Wastes for Energy Recovery. Aerosol and Air Quality Research. doi:10.4209/aaqr.2012.03.0056
  • 11. Jerley, A., Swetha, G., Harini, V., and Priscila, R. 2021. Effects of Biochar and Vermichar as a Soil Supplement to Improve Maize Plant Growth. Asian Journal of Advances in Research, 37-45.
  • 12. Greenberg, A.E., Clescerl, L.S., Eaton, A.D. 2005. Standard methods for the examination of water and wastewater 21th edition. American water works association/American public works association/water environment fedration. ISBN: 0875530478.
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  • 14. Liao, W., and Thomas, S. C. 2019. Biochar particle size and post-pyrolysis mechanical processing affect soil pH, water retention capacity, and plant performance. Soil Systems, 3(1), 14.
  • 15. Li, H., Dong, X., da Silva, E. B., de Oliveira, L. M., Chen, Y., and Ma, L. Q. 2017. Mechanisms of metal sorption by biochars: biochar characteristics and modifications. Chemosphere, 178, 466-478.
  • 16. Liu, H., Chen, Y., Yang, H., Gentili, F. G., Söderlind, U., Wang, X., and Chen, H. 2019. Hydrothermal carbonization of natural microalgae containing a high ash content. Fuel, 249, 441-448.
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  • 18. Mahdi, Z., El Hanandeh, A., and Yu, Q. J. 2015. Date palm (Phoenix Dactylifera L.) seed characterization for biochar preparation. In The 6th international conference on engineering, project, and production management (EPPM) (pp. 2-4).
  • 19. Mahdi, Z., El Hanandeh, A., and Yu, Q. 2017. Influence of pyrolysis conditions on surface characteristics and methylene blue adsorption of biochar derived from date seed biomass. Waste and Biomass Valorization, 8(6), 2061-2073.
  • 20. Mahdi, Z., Qiming, J. Y., and El Hanandeh, A. 2018. Removal of lead (II) from aqueous solution using date seed-derived biochar: batch and column studies. Applied Water Science, 8(6), 1-13.
  • 21. Manna, M. S., and Bhaumik, C. 2021. Opportunities and Challenges in Heavy Metal Removal from Water. In Remediation of Heavy Metals (pp. 347-366). Springer, Cham.
  • 22. Mathijsen, D. 2021. The challenging path to add a promising new bio-fiber from an overlooked source to our reinforcement toolbox: Date palm fibers. Reinforced Plastics, 65(1), 48-52.
  • 23. Mohawesh, O., Coolong, T., Aliedeh, M., and Qaraleh, S. 2018. Greenhouse evaluation of biochar to enhance soil properties and plant growth performance under arid environment. Bulg. J. Agric. Sci, 24, 1012-1019.
  • 24. Nasir, M., Al-Kutti, W., Kayed, T.S., Adesina, A., and Chernykh, T. 2021. Synthesis and SWOT analysis of date palm frond ash–Portland cement composites.Environmental Science and Pollution Research, 1-13.
  • 25. Novak, J. M., Lima, I., Xing, B., Gaskin, J. W., Steiner, C., Das, K. C.,... and Schomberg, H. 2009. Characterization of designer biochar produced at different temperatures and their effects on a loamy sand. Annals of Environmental Science, 3(1), 195-206.
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  • 27. Palágyi, S., Salzer, P., and Mitro, A. 2006. Sorption, desorption and extraction of cadmium from some arable and forest soils. Journal of Radioanalytical and Nuclear Chemistry, 269(1), 103-113.
  • 28. Rao, C.R.M., Sahuquillo, A., and Lopez Sanchez, J.F. 2008. A review of the different methods applied in environmental geochemistry for single and sequential extraction of trace elements in soils and related materials. Water Air Soil Pollut, 189, 291-333.
  • 29. Singh, E., Kumar, A., Mishra, R., You, S., Singh, L., Kumar, S., and Kumar, R. 2021. Pyrolysis of waste biomass and plastics for production of biochar and its use for removal of heavy metals from aqueous solution. Bioresource Technology, 320, 124278.
  • 30. Sutcu, M., Erdogmus, E., Gencel, O., Gholampour, A., Atan, E., and Ozbakkaloglu, T. 2019. Recycling of bottom ash and fly ash wastes in eco-friendly clay brick production. Journal of Cleaner Production, 233, 753-764.
  • 31. Trakal, L., Bingöl, D., Pohořelý, M., Hruška, M., and Komárek, M. 2014. Geochemical and spectroscopic investigations of Cd and Pb sorption mechanisms on contrasting biochars: engineering implications. Bioresource technology, 171, 442-451.
  • 32. Ugulu, I., Khan, Z. I., Aslam, Z., Ahmad, K., Bashir, H., and Munir, M. 2021. Potentially toxic metal accumulation in grains of wheat variety Galaxy-2013 irrigated with sugar industry wastewater and human health risk assessment. Euro-Mediterranean Journal for Environmental Integration, 6(1), 1-11.
  • 33. Ungureanu, O. I., Bulgariu, D., Mocanu, A. M., and Bulgariu, L. 2020. Functionalized PET waste based low-cost adsorbents for adsorptive removal of Cu (II) ions from aqueous media. Water, 12(9), 2624.
  • 34. Usman, A. R., Abduljabbar, A., Vithanage, M., Ok, Y. S., Ahmad, M., Ahmad, M.,... and Al-Wabel, M. I. 2015. Biochar production from date palm waste: charring temperature induced changes in composition and surface chemistry. Journal of Analytical and Applied Pyrolysis, 115, 392-400.
  • 35. Usman, A., Sallam, A., Zhang, M., Vithanage, M., Ahmad, M., Al-Farraj, A., Ok, Y.S., Abduljabbar, A. and Al-Wabel, M. 2016. Sorption process of date palm biochar for aqueous Cd (II) removal: Efficiency and mechanisms. Water, Air, & Soil Pollution, 227(12), 1-16.
  • 36. Zhao, Y., Qamar, S. A., Qamar, M., Bilal, M., and Iqbal, H. M. 2021. Sustainable remediation of hazardous environmental pollutants using biochar-based nanohybrid materials. Journal of Environmental Management, 300, 113762.
  • 37. Zheng, Y., Hua, S., and Wang, A. 2010. Adsorption behavior of Cu2+ from aqueous solutions onto starch-g-poly (acrylic acid)/sodium humate hydrogels. Desalination, 263, 170-175.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-a13baac6-c47d-4c04-9c4a-64074c681639
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