Modulating Photon Harvesting through Constructing Oxygen Vacancies‐Rich 0D/2D Plasmonic Bi/Bismuth Oxybromide Upconversion Nanosheets Towards Improved Solar Photocatalysis

Mullite is an aluminium-silicate mineral of current interest since it is a potential candidate for high temperature applications in the ceramic materials field.In the present work, conditions under which the structure of mullite can be optimally imaged by means of High Resolution Electron Microscopy (HREM) have been investigated. Special reference is made to the Atomic Resolution Microscope at Berkeley which allows real space information up to ≈ 0.17 nm to be directly transferred; numerous multislice calculations (conducted with the CEMPAS programs) as well as extensive experimental through-focus series taken from a commercial “3:2” mullite at 800 kV clearly show that a resolution of at least 0.19 nm is required if one wants to get a straightforward confirmation of atomic models of mullite, which is known to undergo non-stoichiometry associated with the presence of oxygen vacancies.Indeed the composition of mullite ranges from approximatively 3Al2O3-2SiO2 (referred here as 3:2-mullite) to 2Al2O3-1SiO2, and its structure is still the subject of refinements (see, for example, refs. 4, 5, 6).

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Investigation of Some Characterizations of Black TiO\(_2\) Nanotubes Via Spectroscopic Methods

Communications in Physics ◽

10.15625/0868-3166/29/2/13762 ◽

2019 ◽

Vol 29 (2) ◽

pp. 189 ◽

Cited By ~ 1

Author(s):

Tho Truong Nguyen ◽

Thi Minh Cao ◽

Hieu Van Le ◽

Viet Van Pham

Keyword(s):

Water Splitting ◽

Oxygen Vacancies ◽

Light Response ◽

Nanotube Arrays ◽

Spectroscopic Methods ◽

Visible Light Response ◽

Uv Visible ◽

Visible Reflectance ◽

Splitting Effect ◽

Anodization Method

The black TiO\(_2\) with substantial Ti\(^3+\) and oxygen vacancies exhibit an excellent photoelectrochemical water-splitting performance due to the improved charge transport the extended visible light response. In this study, black TiO\(_2\) nanotube arrays synthesized by the anodization method, and then, they have been investigated some characterizations by spectroscopic methods such as UV-visible reflectance (UV-vis DRS), Fourier-transform infrared spectroscopy (FTIR), Raman spectroscopy, and photoluminescence spectrum. The results showed that some highlighted properties of the black TiO2 nanotube arrays and they could apply for water-splitting effect.

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Solar photocatalysis mediated by ZnO for the removal of last traces of Indigo carmine dye pollutant from water

International Journal of Science and Engineering Invention ◽

10.23958/ijsei/vol04-i02/02 ◽

2018 ◽

Vol 4 (02) ◽

Author(s):

Veena Vijayan ◽

Suguna Yesodharan ◽

E. P. Yesodharan

Keyword(s):

Indigo Carmine ◽

Parent Compound ◽

Oxygen Demand ◽

Green Technology ◽

Solar Photocatalysis ◽

Reaction Proceeds ◽

Transient Intermediates ◽

Significant Chemical ◽

Hydroxyl Free Radicals ◽

Purification Of Water

Solar photocatalysis as a potential green technology for the removal of traces of the dye pollutant Indigo carmine (IC) from water is investigated using ZnO as the catalyst. Degradation/decolorization alone does not result in complete decontamination as seen from the significant Chemical Oxygen Demand (COD) of water even after the parent compound has disappeared completely. The degradation proceeds through many intermediates which also get mineralized eventually but slowly. Oxalic acid is identified as a stable slow mineralizing degradation product which itself is formed from other transient intermediates. Effect of various parameters such as catalyst dosage, concentration of the dye, pH, temperature, presence of contaminant salts etc. on the degradation is investigated and quantified. Oxidants such as S2O82- and H2O2 have only moderate influence on the degradation. The degradation follows variable kinetics depending on the concentration of the substrate. The reaction proceeds very slowly in the absence of O2 indicating the importance of reactive oxygen species and hydroxyl free radicals in photocatalysis. H2O2 formed insitu in the system undergoes concurrent decomposition resulting in stabilization in its concentration. The study demonstrates that solar photocatalysis can be used as a viable tool for the purification of water contaminated with traces of IC.

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