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Synthesis and physical properties of micro-nanostructured V2O5: Structure, optical characterization and sunlight photocatalytic activity
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Journal of Material Sciences & Engineering

ISSN: 2169-0022

Open Access

Synthesis and physical properties of micro-nanostructured V2O5: Structure, optical characterization and sunlight photocatalytic activity


35th World Congress on Materials Science and Nanotechnology

July 22-23, 2019 Melbourne, Australia

Top Khac Le and Sok Won Kim

University of Ulsan, South Korea

Scientific Tracks Abstracts: J Material Sci Eng

Abstract :

Bulk V2O5 is a diamagnetic semiconductor with a band gap (Eg) of about 2.3 eV, which is based on the ionic configuration with filled O2p and unoccupied V3d orbitals. However, the special electronic structure of V2O5 forms three bands, including V3d states, V3d split-off states and mid-gap states, which lead to interesting optical properties of V2O5 micro-nanostructures. Therefore, the band edge absorption and Photoluminescence (PL) peak positions of low-dimensional V2O5 material are not coincident. In this study, the fabrication processes, structure, optical characterization and photocatalytic activity of V2O5 micronanostructures, including thin films, nanoparticles, micro-nanorods, micro-nanowires, nanospheres, Nanohollows (NHs) and V2O5/RGO nanocomposites were summarized and analyzed. The wide ranges of band edge absorption and broad PL of V2O5 micro-nanostructures are clarified in terms of factors such as the morphology, synthesis method, growth conditions, micronano size and phase transition. The relations among the separation, diffusion, recombination and degradation of the electronhole pairs in V2O5 micro-nanostructures are also studied. The formation of α-V2O5 films occurred when the sample was annealed at temperatures below 500 °C. As the annealing temperature increases, some of the α-V2O5 structures were distorted and restructured to form a high-quality mixture ofα-β phase V2O5. This leads to wide absorption and enhancement of the visible-light. A larger number of V4+ oxidation states of V2O5 nanospheres strongly enhanced PL intensity compared with other structures that showed weak PL. In particular, V2O5 nanospheres showed intense Ultraviolet (UV) PL near 395 nm (3.14 eV) due to strong excitation by UV light, while this PL peak was not observed from other nanostructures. A large amount of charge separation in V2O5 nanospheres and the large surface contact area in V2O5 nanohollows and nanoparticles result in more efficient photocatalytic activity than from V2O5 micro-nanorods and micro-nanowires.

Biography :

Top Khac Le has completed his Masters in 2012 from University of Science, Vietnam National University HCM City and PhD in 2019 from University of Ulsan, South Korea. He has 3 publishes and 3 submitted publishes (under review) in reputed journals.

E-mail: lktop@hcmus.edu.vn

 

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