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20222
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Subject: Chemistry × End date: 2022 × Start date: 2022 × Thesis Type: Ph.D ×
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    Synthesis of boron and phosphorous doped graphene fabricated with magnesium ferrite – bentonite nanocomposite for the remediation of pollutants
    (Punjab Agricultural University, 2022) Manpreet Kaur; Manpreet Kaur
    Graphene oxide (GO) doped with heteroatoms are gaining interest in depollution of water because of their large surface area. The boron-doped GO (B-GO), phosphorous-doped GO (P-GO) and boron and phosphorous co-doped GO (BPGO) in different w:w ratios were synthesized and fully characterized using analytical techniques viz. FT-IR, XRD, SEM-EDS, TEM, BET, Mössbauer and XPS. In order to impart magnetic features to doped GO materials, magnesium ferrite-bentonite (MGF-B) was used to fabricate nanocomposite of MGF-B and BPGO having hierarchical nanoflowers like morphology (HNFs). TEM of co-doped GO showed more wrinkled surface than doped GO, whereas in case of HNFs, chiffon-like BPGO nanosheets were wrapped on the MGF-B surface, resulting in a porous flower-like morphology. The synthesized materials were explored as adsorbents for the removal of Pb(II) and As(III) ions and as photocatalysts for the degradation of martius yellow, p-nitrophenol and malathion from synthetic waste water. The trend for the percentage removal of heavy metals by adsorption and degradation of organic pollutants by photocatalysis in the descending order was found to be: HNFs > BPGO-1:1 > BPGO-1:5 > BPGO-1:0.2 > MGF-B > P-GO > B-GO > GO. The adsorptive and photocatalytic potential of HNFs was greater as compared to pristine, doped and codoped GO due to high surface area, remarkable charge transfer ability and layered structure of codoped GO sheets. The HNFs possessed appreciable saturation magnetization than doped and co-doped GO layers, which led to its easy separation and reusability. Box-Behnken design was utilized for exploring the simultaneous effects of the independent variables on removal of metal ions and degradation of organic pollutants (as dependent variable) using HNFs. The adsorption and photocatalytic mechanism was proposed on the basis of adsorption isotherm, thermodynamic, kinetic and quenching studies. Enhanced activity of HNFs with adsorption of heavy metal could be defined by the electronic structural properties of elements. The best adsorbent and photocatalyst were also tested for spiked solution containing different metal ions and real life industrial water matrices.
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    Evaluation of doped strontium ferrite nanoparticles functionalized with silica, carbon quantum dots and Cl-doped graphene for the removal of contaminants
    (Punjab Agricultural University, 2022) Grewal, Jaspreet Kaur; Manpreet Kaur
    Doped spinel ferrites and their functionalized nanocomposites with silica (SiO2), carbon quantum dots (CQDs) and chlorine doped graphene oxide (Cl-GO) have attracted immense interest as adsorbents and photocatalysts for water remediation. This work reports the facile strategy for the synthesis and evaluation of Sr1-xTixFe2O4+δ, SiO2, CQDs, Cl-GO and their functionalized nanocomposites for the removal of Cd(II), As(III), p-nitrophenol, pendimethalin and martius yellow from contaminated water. The structural, magnetic, adsorptive and photocatalytic properties were comprehensively studied using different analytical techniques viz. XRD, XPS, FTIR, BET, VSM, TEM, SEM-EDS and 57Mӧssbauer spectroscopy. TEM micrographs revealed the decreased extent of agglomeration in Sr0.4Ti0.6Fe2O4.6 and Sr0.7Ti0.3Fe2O4.3 due to the introduction of non-magnetic Ti4+ ions. TEM image of Sr0.4Ti0.6Fe2O4.6-Cl-GO NC displayed wrinkled nanosheets of Cl-GO containing ferrite NPs with particle size of 25-30 nm distributed over their surface. The fabrication of core-shell nanostructures with SiO2 was clearly visible from their TEM micrographs. The trend for the percentage removal of heavy metals by adsorption and degradation of organic contaminants by photocatalysis in the descending order was found to be: Sr0.4Ti0.6Fe2O4.6-Cl-GO > Sr0.4Ti0.6Fe2O4.6-CQDs > Sr0.4Ti0.6Fe2O4.6@SiO2 > SiO2@Sr0.4Ti0.6Fe2O4.6 > Sr0.4Ti0.6Fe2O4.6. The increased adsorption potential of functionalized nanocomposites as compared to pristine NPs was attributed to the increased surface area, functional moieties, and decreased particle size. The higher photocatalytic efficiency of Sr0.4Ti0.6Fe2O4.6-Cl-GO nanocomposite could be ascribed to the fast charge transfer, stabilization and hindered recombination of electron-hole pairs at the interface of Cl-GO and Sr0.4Ti0.6Fe2O4.6 NPs. Box-Behnken Design (BBD) of response surface methodology was utilized for exploring the simultaneous effects of independent variables on the removal of heavy metal ions and organic pollutants using Sr0.4Ti0.6Fe2O4.6-Cl-GO nanocomposite. The best adsorbent and photocatalyst were also tested for spiked solution containing different metal ions and real life water matrices.