Multifunctional eco-friendly sorbent based on marine brown algae and bivalve shells for subsequent uptake of Congo red dye and copper(II) ions

[Display omitted] •A biosorbent was synthesized based on two copious waste biomass; brown alga and bivalve shells.•Sequential sorption of Congo red dye and copper metal ion was successfully researched.•The designed dye loaded sorbent uptake was 6.94 mmol g−1 (441 mg g−1) of Cu(II) ions.•Feasibility...

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Bibliographic Details
Published in:Journal of environmental chemical engineering 2020-08, Vol.8 (4), p.103915, Article 103915
Main Authors: Elgarahy, A.M., Elwakeel, K.Z., Mohammad, S.H., Elshoubaky, G.A.
Format: Article
Language:English
Subjects:
Anadara shells
Brown algae
Functionalized xerogels beads
Miscellaneous wastewater
Recyclability
Sequential sorption
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Summary:[Display omitted] •A biosorbent was synthesized based on two copious waste biomass; brown alga and bivalve shells.•Sequential sorption of Congo red dye and copper metal ion was successfully researched.•The designed dye loaded sorbent uptake was 6.94 mmol g−1 (441 mg g−1) of Cu(II) ions.•Feasibility of the sorbent to expel Cu(II) from wastewater was successfully appraised. Herein, a novel eco-friendly urea calcium alginate xerogel beads chemically functionalized with Congo red dye (U-CAB-CR1.43) was fabricated on the basis of commercial valorization of two copious waste biomass; Padina boergesenii brown alga and Anadara uropigimelana bivalve shells. The synthesized sorbent was characterized via FT-TR, BET surface area, TGA, SEM and EDX analyses. Sequential sorption capability of as-prepared biosorbent was investigated by appraising its efficiency to capture Cu(II) metal ion under variable operational parameters. Varying of sorbent doses form 0.5 g L−1 to 5 g L−1 was studied. Sorption isotherms, uptake kinetics and thermodynamic studies as prerequisite tools for plausible apprehension of sorption mechanism were also analyzed under optimized pH value (i.e. pH = 6.5). The results revealed that the isotherm profile of U-CAB-CR1.43 fits Langmuir equation with maximum sorption capacity of 6.94 mmol g-1 (441 mg g-1). Kinetic profile was accurately conformed to pseudo-second order rate equation. Thermodynamic function parameters emphasized the endothermic nature of sorption process. Successful desorption scenario using 0.5 mol L−1 of HCl has considerably promoted the spent sorbent to be further used up to four consequent sorption/desorption cycles. Feasibility of productive sorbent to expel Cu(II) from miscellaneous wastewater was successfully researched. To sum up, this study presents an efficient strategy for capturing Cu(II) from miscellaneous wastewater.
ISSN:2213-3437
2213-3437
DOI:10.1016/j.jece.2020.103915