Volume : 08, Issue : 10, October – 2021

Title:

42.COPPER OXIDE NANOPARTICLES AND FARMING SQUANDERS UTILIZED IN IMPROVING THE BIOREMEDIATION AND EXPLANATION STRATEGIES IN MATERIAL EMANATING TREATMENTS

Authors :

Mohd Syeed Shah*, Ghulam Mohammad Jan

Abstract :

Textile dyeing industry is considered as one of the largest generators of wastewater in India, particularly Tiruppur. Dyes released by the textile industries cause a major threat to environmental safety. Apart from physical and chemical method, dye decolourisation through biological means can have a wide range. The present study focused on the screening of microbial isolates from the effluent with respect to the synthetic dye decolourisation. Three bacterial namely Bacillus sp., Pseudomonas sp., Acinetobacter sp. and two laccase producing fungal species, identified as Aspergillus niger and Aspergillus fumigatus, were isolated that were efficient in decolorizing the synthetic dyes. These isolated colonies were used as free cells, microbial consortium and immobilized microbial consortium having the copper oxide nanoparticles, for effluent treatment. Treatment by microbial consortium and immobilized consortium showed better efficiency when compared to individual microbes, but the sludge settlement was again a threat. Effluent treatment by the immobilized microbial consortium with peanut husk and Copper oxide nanoparticles showed promising decolorization and efficient sludge removal during the treatment. By using magnetically induced biological waste the removal of dyes and separation of sludge contents can be achieved with low cost. The process could very well be used in localized companies since it is cost effective and thus aid in the eradication of the scar caused through pollution thus far.
Keywords: Effluent, consortium, immobilization, absorbent, nanoparticles, decolorization.

Cite This Article:

Please cite this article in press Mohd Syeed Shah et al, Copper Oxide Nanoparticles And Farming Squanders Utilized In Improving The Bioremediation And Explanation Strategies In Material Emanating Treatments, Indo Am. J. P. Sci, 2021; 08(10).

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