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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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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creator Kamali, Nima
Rashidi Mehrabadi, Abdollah
Mirabi, Maryam
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description * 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.
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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. 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Environ. Sci. Eng</addtitle><description>* 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%). 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Environ. Sci. Eng</stitle><date>2020-08-01</date><risdate>2020</risdate><volume>14</volume><issue>4</issue><spage>70</spage><pages>70-</pages><artnum>70</artnum><issn>2095-2201</issn><eissn>2095-221X</eissn><abstract>* 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.</abstract><cop>Beijing</cop><pub>Higher Education Press</pub><doi>10.1007/s11783-020-1249-6</doi></addata></record>
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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
title Synthesis of vinasse-dolomite nanocomposite biochar via a novel developed functionalization method to recover phosphate as a potential fertilizer substitute
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