Bottom-up approach synthesis of core-shell nanoscale zerovalent iron (CS-nZVI): Physicochemical and spectroscopic characterization with Cu(II) ions adsorption application

•CS-nZVI was synthesized under anaerobic condition via bottom-up approach.•Physicochemical characterization, Surface functionality and morphology revealed the unique properties of CS-nZVI.•Effective adsorption was achieved in a batch technique while isotherm and kinetic models were statistical valid...

Full description

Saved in:
Bibliographic Details
Published in:MethodsX 2020-01, Vol.7, p.100976-100976, Article 100976
Main Authors: Dada, Adewumi Oluwasogo, Adekola, Folahan Amoo, Odebunmi, Ezekiel Oluyemi, Dada, Fehintoluwa Elizabeth, Bello, Olugbenga Solomon, Ogunlaja, Adeniyi Sunday
Format: Article
Language:English
Subjects:
Characterization
Core shell nZVI
Endocrine disruptive compounds
Isotherms
Kinetics
Materials Science
Morphology
Remediation
Statistical validity
Surface chemistry
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•CS-nZVI was synthesized under anaerobic condition via bottom-up approach.•Physicochemical characterization, Surface functionality and morphology revealed the unique properties of CS-nZVI.•Effective adsorption was achieved in a batch technique while isotherm and kinetic models were statistical validated. Single pot system in chemical reduction via bottom-up approach was used for the synthesis of core shell nanoscale zerovalent iron (CS-nZVI). CS-nZVI was characterized by a combination of physicochemical and spectroscopic techniques. Data obtained showed BET surface area 20.8643 m2/g, t-Plot micropore volume 0.001895 cm3/g, BJH volume pores 0.115083 cm3/g, average pore width 186.9268 Å, average pore diameter 240.753 Å, PZC 5.24, and pH 6.80. Surface plasmon Resonance from UV-Vis spectrophotometer was observed at 340 nm. Surface morphology from SEM and TEM revealed a spherical cluster and chain-like nanostructure of size range 15.425 nm −97.566 nm. Energy Dispersive XRF revealed an elemental abundance of 96.05% core shell indicating the dominance of nZVI. EDX showed an intense peak of nZVI at 6.2 keV. FTIR data revealed the surface functional groups of Fe–O with characteristics peaks at 686.68 cm−1, 569.02 cm−1 and 434 cm−1. In a batch technique, effective adsorption of endocrine disruptive Cu(II) ions was operational parameters dependent. Isotherm and kinetics studies were validated by statistical models. The study revealed unique characteristics of CS-nZVI and its efficacy in waste water treatment. [Display omitted]
ISSN:2215-0161
2215-0161
DOI:10.1016/j.mex.2020.100976