Enhanced adsorption of Fe(II) from synthetic wastewater using modified bentonite: Isotherms, kinetics, thermodynamics, and adsorption mechanisms

The introduction of Fe2⁺ ions into water systems poses significant environmental risks globally. This study investigates the adsorption efficiency of bentonite from the Kongyrtog deposit in Uzbekistan and its modified forms for Fe2⁺ removal from contaminated water. Batch adsorption experiments were...

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Published in:Microporous and mesoporous materials 2025-02, Vol.384, p.113451, Article 113451
Main Authors: Khandamov, Davron Abdikodirovich, Kurniawan, Tonni Agustiono, Bekmirzayev, Akbarbek Shukhratovich, Batool, Fatima, Khandamova, Dilnoza, Nurullayev, Shavkat, Kholikova, Sevara, Babakhanova, Zebo, Hayet Khan, Md Munir
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Language:English
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Adsorption
Clean water
Heavy metals
Natural adsorbent
Wastewater treatment
Water pollution
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creator Khandamov, Davron Abdikodirovich
Kurniawan, Tonni Agustiono
Bekmirzayev, Akbarbek Shukhratovich
Batool, Fatima
Khandamova, Dilnoza
Nurullayev, Shavkat
Kholikova, Sevara
Babakhanova, Zebo
Hayet Khan, Md Munir
description The introduction of Fe2⁺ ions into water systems poses significant environmental risks globally. This study investigates the adsorption efficiency of bentonite from the Kongyrtog deposit in Uzbekistan and its modified forms for Fe2⁺ removal from contaminated water. Batch adsorption experiments were conducted with Fe2⁺ concentrations of 2.0–20 mg/L, at pH 7.0, an adsorbent dose of 1 g/L, and temperatures between 288 and 308 K. The bentonites were named MED (modified with ethylenediammoniumdihydrochloride) and MGD (modified with hexamethylenediammonium dihydrochloride), while NKB refers to natural bentonite. Multiple linear regression (MLR) modeling validated the adsorption process, with high R2 correlation coefficients supporting the Langmuir model. Optimal adsorption conditions included a dose of 1 g/L, pH 5.2, a contact time of 40 min, and a temperature of 308 K, with the adsorption kinetics fitting a pseudo-second-order model. Using the Langmuir isotherm model, the maximum adsorption capacities (qmax) were determined as 8.47 mg/g for NKB, 8.51 mg/g for MGD, and 10.84 mg/g for MED. Among the modified bentonites, Fe2⁺ adsorption followed the activity sequence MED > MGD > NKB, with intraparticle diffusion modeling suggesting a two-stage adsorption process. The negative Gibbs free energy values (ΔG°) confirmed the process was spontaneous and endothermic. These modified bentonites offer a cost-effective alternative to activated carbon with the ability to regenerate up to four times. Initial regeneration efficiencies were 78 % for NKB, 83 % for MGD, and 86 % for MED. This study demonstrates the potential of modified bentonites as sustainable adsorbents for Fe2⁺ removal, contributing to advancements in eco-friendly water treatment technologies. [Display omitted] •Adsorption capacity (qmax) of ethylenediammonium bentonite was 10.84 mg of Fe/g.•Optimal conditions for Fe2+ adsorption: pH 5.2, 1.0 g/L of dose, 308K of temperature.•Fe2+ adsorption by bentonite is endothermic and followed pseudo-second-order model.•Fe2+ adsorption by ethylenediammonium bentonite was 90 % at 2 mg/L of its concentration.•Fe2+ removal by hexamethylenediammonium bentonite was 80 % at the same Fe concentration.
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This study investigates the adsorption efficiency of bentonite from the Kongyrtog deposit in Uzbekistan and its modified forms for Fe2⁺ removal from contaminated water. Batch adsorption experiments were conducted with Fe2⁺ concentrations of 2.0–20 mg/L, at pH 7.0, an adsorbent dose of 1 g/L, and temperatures between 288 and 308 K. The bentonites were named MED (modified with ethylenediammoniumdihydrochloride) and MGD (modified with hexamethylenediammonium dihydrochloride), while NKB refers to natural bentonite. Multiple linear regression (MLR) modeling validated the adsorption process, with high R2 correlation coefficients supporting the Langmuir model. Optimal adsorption conditions included a dose of 1 g/L, pH 5.2, a contact time of 40 min, and a temperature of 308 K, with the adsorption kinetics fitting a pseudo-second-order model. 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This study investigates the adsorption efficiency of bentonite from the Kongyrtog deposit in Uzbekistan and its modified forms for Fe2⁺ removal from contaminated water. Batch adsorption experiments were conducted with Fe2⁺ concentrations of 2.0–20 mg/L, at pH 7.0, an adsorbent dose of 1 g/L, and temperatures between 288 and 308 K. The bentonites were named MED (modified with ethylenediammoniumdihydrochloride) and MGD (modified with hexamethylenediammonium dihydrochloride), while NKB refers to natural bentonite. Multiple linear regression (MLR) modeling validated the adsorption process, with high R2 correlation coefficients supporting the Langmuir model. Optimal adsorption conditions included a dose of 1 g/L, pH 5.2, a contact time of 40 min, and a temperature of 308 K, with the adsorption kinetics fitting a pseudo-second-order model. Using the Langmuir isotherm model, the maximum adsorption capacities (qmax) were determined as 8.47 mg/g for NKB, 8.51 mg/g for MGD, and 10.84 mg/g for MED. Among the modified bentonites, Fe2⁺ adsorption followed the activity sequence MED &gt; MGD &gt; NKB, with intraparticle diffusion modeling suggesting a two-stage adsorption process. The negative Gibbs free energy values (ΔG°) confirmed the process was spontaneous and endothermic. These modified bentonites offer a cost-effective alternative to activated carbon with the ability to regenerate up to four times. Initial regeneration efficiencies were 78 % for NKB, 83 % for MGD, and 86 % for MED. This study demonstrates the potential of modified bentonites as sustainable adsorbents for Fe2⁺ removal, contributing to advancements in eco-friendly water treatment technologies. 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subjects Adsorption
Clean water
Heavy metals
Natural adsorbent
Wastewater treatment
Water pollution
title Enhanced adsorption of Fe(II) from synthetic wastewater using modified bentonite: Isotherms, kinetics, thermodynamics, and adsorption mechanisms
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