Synthesis of vinasse-dolomite nanocomposite biochar via a novel developed functionalization method to recover phosphate as a potential fertilizer substitute

* Nanocomposites were prepared by adding dolomite to vinasse at different ratio. * Textural and morphological features of adsorbents were studied in detail. * CCD based RSM was used for investigation of P ion removal by nanocomposite. * The q m based on Langmuir model for modified vinasse biochar wa...

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Bibliographic Details
Published in:Frontiers of environmental science & engineering 2020-08, Vol.14 (4), p.70, Article 70
Main Authors: Kamali, Nima, Rashidi Mehrabadi, Abdollah, Mirabi, Maryam, Zahed, Mohammad Ali
Format: Article
Language:English
Subjects:
Adsorption
Anions
Aqueous solutions
Biochar
Charcoal
Dolomite
Earth and Environmental Science
Environment
Fertilizer
Fertilizers
Nanocomposites
Phosphate
Pyrolysis
Research Article
Response surface methodology
Substitutes
Surface chemistry
Synthesis
Vinasse
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Summary:* Nanocomposites were prepared by adding dolomite to vinasse at different ratio. * Textural and morphological features of adsorbents were studied in detail. * CCD based RSM was used for investigation of P ion removal by nanocomposite. * The q m based on Langmuir model for modified vinasse biochar was 178.57 mg/g. * P loaded nanocomposite improved plant growth and could be utilized as P-fertilizer. The effectiveness of phosphate (P) removal from aqueous solutions was investigated by novel low-cost biochars synthesized from vinasse and functionalized with calcined dolomite. The vinasse-derived biochar, synthesized via pyrolysis at different temperatures, showed easy preparation and a large surface area. The novel vinasse biochar nanocomposites were prepared by adding dolomite to the vinasse biochars with different weight percentages (10, 20 and 30%). The characteristics of the prepared materials were identified for further understanding of the inherent adsorption mechanism between P ions and vinasse biochars. Vinasse-dolomite nanocomposite was very effective in the adsorption of P species from aqueous media. The effect of the operational factors on Vinasse-dolomite nanocomposite was explored by applying response surface methodology (RSM). According to RSM results, the optimum condition was achieved to be contact time 90 (min), 250 (mg/L) of P concentration and pH 7. Thermodynamic isotherm and kinetic studies were applied on experimental data to understand the adsorption behavior. The Vinasse-dolomite nanocomposite revealed preferential P species adsorption in the presence of co-existing anions. The P species could be recovered by 1.0 M HCl where the efficiency was not affected up to the fifth cycle. The P-loaded Vinasse-dolomite nanocomposite was successfully tested on a plant; it significantly improved its growth and proved its potency as a P-based fertilizer substitute.
ISSN:2095-2201
2095-221X
DOI:10.1007/s11783-020-1249-6