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Remediation of water containing lead(II) using (3-iminodiacetic acid) propyltriethoxysilane graphene oxide

Ayyob M. Bakry, Nasser Amri, Mina Shawky Adly, Abdullah Alamri, Reda S. Salama, Abdulmajeed M. Jabbari, M. Samy El‐Shall, Fathi S. Awad

2024Scientific Reports20 citationsDOIOpen Access PDF

Abstract

A novel chelating adsorbent based on (3-iminodiacetic acid) propyltriethoxysilane graphene oxide (IAT-GO) has been developed, showing exceptional promise for capturing lead. IAT-GO is made by combining a high-surface-area graphene oxide with a specially designed chelating ligand, which can selectively and efficiently remove lead. The synthesis of IAT-GO involves a two-step progression. In the first step, covalent bonds form between graphene oxide and (3-aminopropyl)-triethoxysilane (AT) through hydrolysis, condensation, and epoxide ring opening reactions. In the second step, nucleophilic substitution reactions occur between the primary amines and chloroacetic acid (CAA). A comprehensive suite of characterization techniques, including XPS, UV-Vis, XRD, Raman, FTIR, TEM, and SEM, provides detailed insights into the IAT-GO adsorbent's chemical composition and physical form, elucidating its intricate structure and morphology. Optimizing the experimental conditions for using the adsorbent material to remove Pb(II) ions from contaminated water revealed a maximum adsorption capacity of 124.0 mg/g at pH 5 and 30 min. The IAT-GO displays high selectivity for Pb(II) in a mixture of six metal ions containing 100 ppm of each one. Moreover, the IAT-GO shows 100% removal of Pb(II) for concentrations lower than 50 ppm. The excellent fit of the experimental data with the Langmuir adsorption isotherm and pseudo-second-order kinetic models (R2 > 99%) indicates that Pb(II) ion uptake onto the IAT-GO surface occurs via the monolayer formation of mercury ions. IAT-GO demonstrates exceptional potential as an innovative adsorbent for lead-contaminated water. Nitric acid (0.4 M) effectively regenerates the material, while its reusability remains impressive even after five cycles (> 97% removal efficiency). Therefore, this study highlights the development of a groundbreaking material, IAT-GO, with exceptional potential for remediating lead-contaminated water. Its high efficiency, selectivity, reusability, and cost-effectiveness make it a promising candidate for real-world applications.

Topics & Concepts

GrapheneIminodiacetic acidEnvironmental remediationOxideLead (geology)Lead oxideEnvironmental chemistryChemistryEnvironmental scienceMaterials scienceNanotechnologyMetallurgyInorganic chemistryGeologyContaminationBiologyEcologyChelationGeomorphologyGraphene and Nanomaterials ApplicationsAdsorption and biosorption for pollutant removalNanomaterials for catalytic reactions
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