Uncovering nano-bonechar for attenuating fluoride in naturally contaminated soil

Fluoride ion (F−) is one of the major geogenic contaminants in water and soil. Excessive consumption of these geogenic contaminants poses serious health impacts on humans and plants. In this study, a novel carbonaceous material, nano-bonechar, was synthesized from cow bones and applied as a soil ame...

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Published in:Chemosphere (Oxford) 2024-04, Vol.353, p.141490-141490, Article 141490
Main Authors: Imtiaz, Hina, Khan, Matiullah, Khan, Basit Ahmed, Shahid, Saher, Rajapaksha, Anushka Upamali, Ahmad, Mahtab
Format: Article
Language:English
Subjects:
Economical remedy
Feedstock
Fluorides
Humans
Hydroxyapatites
Immobilization
Nano-hydroxyapatite
Pyrolysis
Soil
Soil Pollutants - analysis
Soil quality
Water
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Summary:Fluoride ion (F−) is one of the major geogenic contaminants in water and soil. Excessive consumption of these geogenic contaminants poses serious health impacts on humans and plants. In this study, a novel carbonaceous material, nano-bonechar, was synthesized from cow bones and applied as a soil amendment at rates of 0, 0.5, 1, and 2% to remediate and revitalize naturally F−-contaminated soil. The results revealed that the nano-bonechar significantly reduced the mobility and bioavailability of F− by 90% in the contaminated soil, and improved the soil quality by increasing the soil water holding capacity, soil organic matter, and the bioavailable contents of PO43−, Ca2+, and Na+. Subsequently, the pot experiment results showed a significant reduction in the uptake of F- by 93% in Zea mays plants. Moreover, the nano-bonechar application improved the plant's growth, as indicated by the higher fresh and dry weights, root and shoot lengths, and total content of PO43−, Ca2+, and K+ than those of un-amended soil. The F-immobilization in soil was mainly due to the presence of the hydroxyapatite [Ca10(PO4)6(OH)2] mineral in the nano-bonechar. Ion exchange between OH− (of nano-bonechar) and F− (of soil), and the formation of insoluble fluorite (CaF2) contributed to the attenuation of F− mobility in the soil. It is concluded that nano-bonechar, due to its size and enrichment in hydroxyapatite, could successfully be utilized for the rapid remediation and revitalization of F−-contaminated agricultural soil. [Display omitted] •A novel material, nano-bonechar, was produced from cow bones via pyrolysis and milling.•Nano-bonechar immobilized 90% F− in naturally contaminated agricultural soil.•Nano-bonechar tended to bind F− as fluorite (CaF2) and fluorapatite [Ca10(PO4)6F2].•F− uptake by Zea mays was significantly reduced by 93% in the amended soil.•PO43−, Ca2+, and K+ uptake by Zea mays significantly enhanced in the amended soil.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2024.141490