Egyptian seaweed resources from the South Sinai coast to develop alginate-based biohybrid composites for enhanced lead(II) removal from industrial wastewater

Authors

Yomna M. Hashish, College of Science
M. A. Ahmed, College of Science
Tarek M. Madkour, The American University in Cairo
Mohamed A. Mekewi, College of Science
Atef S. Darwish, College of Science

Third Author's Department

Chemistry Department

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https://doi.org/10.1016/j.dwt.2024.100929

All Authors

Yomna M. Hashish, M. A. Ahmed, Tarek M. Madkour, Mohamed A. Mekewi, Atef S. Darwish

Document Type

Research Article

Publication Title

Desalination and Water Treatment

Publication Date

1-1-2025

doi

10.1016/j.dwt.2024.100929

Abstract

Herein, crosslinked-alginate (CAL) was extracted from Egyptian marine biowaste (brown seaweed discarded near seashore of Ras Sedr, Sinai). Novel biohybrid composites were fabricated by hybridizing CAL chains with either carbohydrate polymer (starch, St) or proteinaceous content (albumin, Alb). Physicochemical properties of such biocomposites were characterized using XRD, FTIR, Raman, DLS, SEM and AFM analyses. Compared to CAL, starch as hybridizing agent enthuses existence of stacking-oriented alginate chains of higher amorphicity and lower zeta-potential (−17 mV). Hybridization of alginate matrix with albumin chains yielded high negatively charged (−37.8 mV) crystalline biocomposite with smooth surfaces. Performance of St-CAL and Alb-CAL biocomposites toward Pb2+ removal from wastewater was scrutinized. The impact of pH, adsorbate concentration, contact time, and thermodynamic studies on Pb2+ removal using these biocomposites were estimated. Removal efficiency of St-CAL was superior to that of Alb-CAL yielding ∼ 70 % for 5 succussive runs. Pb2+ adsorption process over St-CAL was spontaneous with exothermic nature at room temperature and followed Freundlich model with pronounced adsorption energy and capacity. Fitness of kinetic models for St-CAL was ranked as pseudo-first-order with escalated intra-particle diffusion rates. Construction of oxygen-rich hybrid carbohydrate systems is willingly applied in future as green cleaner to wastewater from heavy metal ions.

Comments

Article. Record derived from SCOPUS.

Recommended Citation

APA Citation

Hashish, Y. Ahmed, M. Madkour, T. Mekewi, M. & Darwish, A. (2025). Egyptian seaweed resources from the South Sinai coast to develop alginate-based biohybrid composites for enhanced lead(II) removal from industrial wastewater. Desalination and Water Treatment, 321, 10.1016/j.dwt.2024.100929
https://fount.aucegypt.edu/faculty_journal_articles/6148

MLA Citation

Hashish, Yomna M., et al. "Egyptian seaweed resources from the South Sinai coast to develop alginate-based biohybrid composites for enhanced lead(II) removal from industrial wastewater." Desalination and Water Treatment, vol. 321, 2025,
https://fount.aucegypt.edu/faculty_journal_articles/6148