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Preparation of mixed manganese oxide nano-matrix and studies on its oxidative and pathogenic activities

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dc.contributor.advisor Manwarul Islam, Dr. Md.
dc.contributor.author Aminul Islam, Md.
dc.date.accessioned 2015-12-14T10:06:37Z
dc.date.available 2015-12-14T10:06:37Z
dc.date.issued 2015-02
dc.identifier.uri http://lib.buet.ac.bd:8080/xmlui/handle/123456789/1522
dc.description.abstract Nanotechnology is an emerging interdisciplinary subject that has been booming in many areas during the recent decade. Looking into this aspect, black MnO2 nanoparticles (nps) have been synthesized, via a facile one stop solution phase approach, by co-precipitation method by the reduction from a system containing KMnO4 and MnSO4 solutions. Pure phase, spherical, uniformly dispersed brown Mn3O4 nps powder was synthesized successfully by forced hydrolysis of Mn(II) acetate by heating its aqueous solution at 800C. Blackish brown γ−MnOOH nps was synthesized by a simple route using Mn(II) acetate as precursor by hydrothermal treatment. The evidence of MnO2, Mn3O4 and γ−MnOOH nps formation under the synthesis conditions were confirmed by UV–vis spectra, FT-IR, XRD, SEM, EDX, DLS, TG-DTA, pHpzc and Specific Surface Area (SSA) analysis. FT-IR spectra of MnO2 nps showed the occurrence of O–Mn–O vibrational mode at around 571 and 535 cm-1. The selected area electron diffraction patterns revealed that the MnO2 was crystalline and rod like in nature. Elemental analysis exhibited the presence of Mn and oxygen elements in the MnO2, Mn3O4 and γ−MnOOH and no foreign elements in them. The average crystallite size was calculated from the XRD data for MnO2, Mn3O4 and γ−MnOOH nps were approximately 7.0 nm, 10.0 nm and 11.0 nm respectively. The specific surface area of γ−MnOOH nps was found to be 142.962 and 195.747 (m2 g- 1) respectively. Oxidative decolorization of MB and OG were studied at different pH, concentration, adsorbent dose and contact time by UV-Vis spectroscopy. From kinetic analysis, it was found that decolorization is dependent on parameters such as dye concentration, Mn-oxide doses, pH and other parameters. The observed results were in good agreement with experimental data. The decolorization data showed that both MB and OG could be decolorized by Mnoxide surface. But the extent of MB decolorization was much higher than OG, suggesting the present γ−MnOOH nps can be used as a highly efficient material for oxidative decolorization of MB. MB decolorization was through a surface mechanism, that is, formation of surface precursor complex between MB and surface bound MnOOH center, followed by electron transfer within the surface complex. Kinetic study demonstrated that both MB and OG decolorization followed pseudo-secondorder kinetic. The experimental isotherm results were fitted using Langmuir, Freundlich, Temkin and Sips isotherm. The Freundlich model agreed very well with experimental data. The pathogenic experiment was performed following the standard conventional method by treating the Mn-oxides nps in 7.5% (v/v) DMSO suspension to various pathogenic organisms. The experiments were performed duplicate and triplicate. From the experimental evidence it was clear that Mn-oxides did not have potential antibacterial activity. en_US
dc.language.iso en en_US
dc.publisher Department of Chemistry (Chy) en_US
dc.subject Nanocomposite materials en_US
dc.subject Nanotechnology en_US
dc.title Preparation of mixed manganese oxide nano-matrix and studies on its oxidative and pathogenic activities en_US
dc.type Thesis-MPhil en_US
dc.contributor.id 0412033203 P en_US
dc.identifier.accessionNumber 113422
dc.contributor.callno 620.5/AMI/2015 en_US


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