Utilizing biosorbents for sustainable mercury removal from aqueous solutions: Efficiency and practical applications

Utilizing biosorbents for sustainable mercury removal from aqueous solutions: Efficiency and practical applications

Mercury contamination in water bodies presents serious health risks and ecological challenges because of its hazardous nature and long-lasting presence. Traditional remediation methods frequently lead to secondary pollution or lack sustainability. This research explores the feasibility of activated...

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Bibliographic Details
Main Authors: Rahele Khosravi Nessiani, Meysam Naseri, Hadi Erfani, Sajjad Khodayari, Sumarlin Shangdiar, Kassian T.T. Amesho
Format: Article
Language:English
Published: Elsevier 2025-04-01
Series:Desalination and Water Treatment
Subjects:
Mercury remediation
Aquatic toxicity
Adsorption dynamics
Environmental sustainability
Biosorption efficiency
Wastewater treatment
Online Access:http://www.sciencedirect.com/science/article/pii/S1944398625001390
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Summary:Mercury contamination in water bodies presents serious health risks and ecological challenges because of its hazardous nature and long-lasting presence. Traditional remediation methods frequently lead to secondary pollution or lack sustainability. This research explores the feasibility of activated carbon produced from Christ's Thorn tree leaves as an innovative and affordable biosorbent for removing mercury ions (Hg(II)). Optimal adsorption parameters were identified as a pH of 7.5, a contact duration of 90 minutes, an initial mercury level of 0.25 mg/L, and a biosorbent amount of 0.2 g. Under these conditions, the maximum adsorption capacity (qmax) was determined to be 0.83 mg/g, achieving a removal rate of 87 %. The adsorption mechanism was most accurately explained by the Freundlich isotherm (R2 = 0.96, AARD = 5.2 %), indicating multilayer uptake on an uneven surface. Kinetic analysis showed that the pseudo-second-order (PSO) model gave the most accurate prediction (R2 = 0.98, AARD = 4.5 %), implying that chemical bonding was the primary mechanism. Moreover, the Elovich model effectively described the initial sorption speed, further confirming the strong interaction between Hg(II) ions and the biosorbent. The material's reusability across seven cycles with minimal performance degradation underscores its potential for practical mercury remediation applications. This work highlights the efficiency, eco-friendliness, and cost-effectiveness of Christ's Thorn tree leaves as a biosorbent, offering a promising approach for mercury extraction from potable water and industrial effluents. Future investigations should focus on upscaling for industrial deployment and evaluating its performance for other toxic metals.
ISSN:1944-3986

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