Highly selective and efficient Pb2+ capture using PO4-loaded 3D-NiFe layer double hydroxides derived from MIL-88A

Lead (Pb) contamination in water requires improved decontamination technologies. The addition of phosphate to precipitate Pb2+ is a widely used method for remediating Pb in soil and water, though it has certain limitations. This study focuses on novel 3D mesoporous layered double hydroxide (LDH) sor...

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Bibliographic Details
Published in:Chemosphere (Oxford) 2024-09, Vol.364, p.143070, Article 143070
Main Authors: Li, Mengwei, Prévot, Vanessa, You, Zhixiong, Forano, Claude
Format: Article
Language:English
Subjects:
3D MOF-Derived layered double hydroxides
Chemical Sciences
Environmental Sciences
Pb2+ adsorption
Pb3(PO4)2 surface precipitation
Phosphate functionalization
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Summary:Lead (Pb) contamination in water requires improved decontamination technologies. The addition of phosphate to precipitate Pb2+ is a widely used method for remediating Pb in soil and water, though it has certain limitations. This study focuses on novel 3D mesoporous layered double hydroxide (LDH) sorbents functionalized with phosphate anions for Pb2+ removal from contaminated waters. Our innovative strategy involves converting a sacrificial template metal-organic frameworks (MOFs) structure (MIL-88A(Fe)) into NixFe LDH, followed by an anion exchange reaction with phosphate anions. This process preserves the 3D microrod architecture of MIL-88A and prevents deleterious LDH particle aggregation. The synthesis results in stable microrod crystals, 1–2 μm long, composed of 3D assemblies of NixFe-PO4 LDH nanoplatelets with a specific surface area exceeding 110 m2/g. The novel LDH materials display fast adsorption kinetics (pseudo-second order model) and remarkably high Pb2+ removal performances (Langmuir isotherm model) with a capacity of 538 mg/g, surpassing other reported adsorbents. LDH-PO4 exhibits high selectivity for Pb2+ over competing ions like Ni2+ and Cd2+ (selectivity order is: Pb2+ > Ni2+ > Cd2+). Removal of Pb2+ from NixFeLDH/88A-PO4 involves various mechanisms, including surface complexation and surface precipitation of lead phosphate or lead hydroxide phases as revealed by structural characterization techniques. [Display omitted] •Novel 3D mesoporous microrod NixFe-PO4 LDHs from MIL-88 conversion.•Highest Pb2+ adsorption capacity 537.6 mg/g (pH 7) of Ni3Fe-PO4 LDHs.•Selectivity of NixFe-PO4 LDHs for heavy metals in order: Pb2+ > Ni2+ > Cd2+.•Pb2+ removal through surface precipitation mechanisms of Pb3(PO4)2 and Pb(OH)2.
ISSN:0045-6535
1879-1298
1879-1298
DOI:10.1016/j.chemosphere.2024.143070