Design and Development of Hybrid Nanomaterials for Efficient Photocatalysis

dc.contributor.authorDevi, Thongam Debika
dc.date.accessioned2024-05-17T10:27:38Z
dc.date.available2024-05-17T10:27:38Z
dc.date.issued2024
dc.descriptionSupervisor: Chaturvedi, Harshen_US
dc.description.abstractWater is our life and its quality degradation has imposed a major threat to the health and environment with the emerging contaminants. Photocatalytic advanced oxidation processes (AOP) using reactive oxygen species (OH¯, •OH, H2O2, HO2•, O2•¯, O22¯) provide complete degradation of these persistent pollutants by using nanomaterials triggered by light absorption. However, its real-time application is limited by the use of high-power light sources to trigger the reaction and its limited performance. Thus, this thesis focuses on understanding and addressing these bottlenecks by― (a) designing and developing a sunlight-responsive photocatalyst to harvest natural sunlight, (b) developing heterostructure photocatalysts for enhanced efficiency by developing interfacial charge transfer, and (c) studying and discovering ways to enhance charge transfer by manipulating heterostructure photocatalyst responsive to natural sunlight. To achieve efficient photocatalysis, different sunlight-responsive photocatalysts were synthesized by varying― synthesis mediums and methods introducing surface defects and producing different nanoparticle morphologies. The dependence of the charge transfer, charge carrier lifetimes, surface structures, induced defects, and morphologies on the photocatalytic efficiencies were discussed elaborately. Variable ZnO samples were synthesized using DMF or DEG solvents using solvothermal and chemical synthesis methods showing different properties― morphologies, surface, and chemical properties. The influence of the charge transfer pathways in the photocatalytic efficiencies is discussed and explored with different charge transfer methods― self-assembled ZnO nanoparticles on three electronically different SWCNTs (metallic-SWCNT/ZnO, semiconducting-SWCNT/ZnO, and pristine-SWCNT/ZnO); Type I ZnO/Fe3O4 and Type II ZnO/TiO2 composite heterostructures; g-C3N4 & Z-scheme g-C3N4/ZnO composites, and other composites― g-C3N4/SWCNT, and g-C3N4/ZnO/SWCNT. By taking RhB as a model pollutant, these nanoparticles were used as the floating photocatalyst by coating on the face-mask fabric showing variable efficiencies up to 99% of 10 ppm RhB degradation within the 100 min natural sunlight exposure.en_US
dc.identifier.otherROLL NO.176151105
dc.identifier.urihttps://gyan.iitg.ac.in/handle/123456789/2617
dc.language.isoenen_US
dc.relation.ispartofseriesTH-3354;
dc.subjectHeterostructure Interfaceen_US
dc.subjectNatural Sunlight-responsive Floating Photocatalysten_US
dc.subjectCharge Transfer Dynamicsen_US
dc.subjectReactive Oxygen Speciesen_US
dc.subjectMorphologiesen_US
dc.subjectInduced Defectsen_US
dc.subjectReuse Face-mask Fabricen_US
dc.titleDesign and Development of Hybrid Nanomaterials for Efficient Photocatalysisen_US
dc.typeThesisen_US
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