Abstract:
Industrial dye effluents are a significant concern and require to be treated before
being discharged into the environment. Magnesium oxide (MgO) has been known
as an excellent adsorbent for a variety of environmentally polluted compounds.
This study synthesizes Fe@MgO nanocomposites via a facile precipitation calcination approach by using tetraethyl orthosilicate (TEOS) as a protective and
coupling agent to remove the methylene blue in the wastewater. Powder X-ray
diffraction analyses (XRD) were performed to characterize the physical properties
of synthesized Fe@MgO nanocomposites and scanning electron microscopy
(SEM) was used to observe their morphology and particle size, and the X-ray
photoelectron spectroscopy (XPS) method was used to obtain the elemental
composition as well as the chemical and electronic state of the atoms within a
material. The adsorption performance was studied by batch experiments using a
UV- vis spectrometer for methylene blue dye (MBD) removal. The results showed
that as-prepared Fe@MgO nanocomposites are composed of cubic structures of
Fe, Fe3O4, and MgO with granular morphology. Fe3O4 shows magnetic properties
while, Mg, Fe, and O are in the electronic configuration of 1s, 2p, and 1s with
1302.2 eV, 710 eV, and 530 eV respectively. The contact time of the as-prepared
Fe@MgO for methylene blue dye was 120 min. Langmuir model fitted better with
the experimental data of methylene blue adsorption with higher correlation
coefficients (R2>0.9911), suggesting the methylene blue adsorption onto
Fe@MgO is monolayer chemisorption. Furthermore, the maximum adsorption
capacity (QM) calculated by the Langmuir model was 1857.0 mg g-1 which was
close to the experimental value of 1440.0 mg g-1
. It was found that the adsorption
process was very fast, and the adsorption capacity of Fe@MgO was higher
compared to Fe3O4/carboxymethyl-β-cyclodextrin (CM-β-CD), MgFe2O3@SiO2,
and Cobalt zinc ferrite.
