International Journal of Photochemistry

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The VO4-TiO2 nanocomposite material prepared by precipitation method using sonication technique. The material has characterized by High-resolution of scanning electron microscopy (HR-SEM) with elementary dispersive X-ray (EDX) analysis, XRD analysis and photoluminescence spectroscopy (PL) analysis. The experimental results exposed that 5000C of material exhibited in the higher photoatalytic activity in Trypan Blue (TB) dye under UV-Light irradiation at 365 nm. Nanocomposite material is applicable for photodegradation of waste water treatment and environmental problem found to be the stable and reusable then important uses in an industrial water effluents and many manufacturing industries.

Keywords: Photocatalytic activity, Trypan Blue (TB), HR-SEM

H.K. Shon, S. Phuntsho, S. Vigneswaran, Effect of photocatalysis on the membrane hybrid system for waste water treatment, Desalin. Water Treat. 225 (2008) 235–248.

. D. Yiamsawas, K. Boonpavanitchakul, W. Kangwansupamonkon, J. Microsc. Soc. Thailan. 23(2009) 75-78.

. S. Balachandran, N. Prakash, K. Thirumalai, M. Muruganandham, M. Sillanpaa

M. Swaminathan, Ind. Eng. Chem. Res, 53 (2014) 8346-8356.

. S. Balachandran, M. Swaminathan Dalton Trans., 42 (2013) 5338-5347.

. H.K. Shon, S. Phuntsho, S. Vigneswaran Desalin Water Treat. 225 (2008) 235–248.

. R. J. Davis, Z. Liu Titania-silica: a model binary oxide catalyst system,” Chemistry of Materials, 9 (1997) 2311–2324.

. Z. Liu, R. J. Davis Journal of Physical Chemistry, 98 (1994) 1253–1261.

. H. A, Benesi, B. H. C Winquist, Adv. in Catal, 27 (1979) 97–182.

. J. Göttsche, A. Hinsch V. Wittwer, Sola Ener. Mater. and Solar Cells, 31 (1993) 415–428.

. I, Shiyanovskaya M. Hepel, Journal of the Electrochem. Society, vol. 146 (1999) 243–249.

. D. Camino D. Deroo, J. Salardenne, N. Treuilm, Sol. Ener. Mater. and Solar Cells, 39 (1995) 349–366.

. Y. Wu, L. Hu,. Z Jiang, Q. Ke, Journal of the Electrochem . Society, 144 (1997) 1728–1733.

. S. K, Poznyak, D. V,Talapin, A. Kulak, J. of Phy. Chemist. B, 105 (2002) 4816–4823.

. D. Liu, P. V. Kamat Journal of Physical Chemistry, 97 (1993) 10769–10773.

. R. Suarez, P. K. Nair, and P. V. Kamat, Langmuir, 14 (1998) 3236–3241

. Yoon K. H, Cho J, Kang D. H, Materials Res. Bulletin, 34 (1999) 1451–1461.

. J. Su, L, Guo, N. Bao, C. A, Grimes, Nano Lett, 11 (2011) 1928–1933.

. F. Haimei, W. Dejun, L. Zhipeng, X. Tengfeng, L. Yanhong, Dalton Trans. 44 (2015)

J.F. Zhu, Z.G. Deng, F. Chen, J.L. Zhang, H.J. Chen, M. Anpo, J.Z. Huang, L.Z. Zhang,

. S. Parsons, Advanced Oxidation Processes for Water and Wastewater, IWA Publishing, London, UK (2004).

. M. Zubair Alam, S. Ahmad, A. Malik, M. Ahmad, Ecotoxicology and Environ. Safety 73 (2010) 1620–1628.

. C. O'Neill, A. Lopez, S. Esteves, F.R. Hawkes, D.L. Hawkes, S. Wilcox, Applied Microbiol. and Biotechnol. 53 (1999) 249–254.

. William L. Kostedt, IV Adel, A. Ismailm and David W. Mazyck, Desalination 276 (2011) 13–27

J. Kamalakkannan, and S. Senthilvelan, WSN 6 (2017) 338-364

S. Balachandran, G.Sarojini, b. Praveen, R. Velmuruganc and M. Swaminathan, RSC Adv. (2014) 4353–4362

. K. Ameta, P. Tak, D. Soni and S.C. Ameta, Sci. Rev. Chem. Commun., 4 (2014)