Abstract
Nanotechnology is a recent field of modern research dealing with synthesis, strategy and manipulation of particle’s structure in size range of 1–100 nm. This study introduces one of the methods of synthesis of nanoparticles, i.e., green synthesis of ZnO NPs using aqueous leaf extract of Becium grandiflorum (AM: ‘Yedegamentisie’). The biomolecules of the plant extract (such as phenols, flavonoids, saponins, glycosides, steroids, tannins and alkaloids) were used as capping and reducing agent during synthesis of ZnO NPs. Response surface methodology coupled with Box-Behnken design (RSM-BBD) was used to optimize the synthesis of ZnO NPs and adsorption studies of the as-synthesized ZnO NPs. Then, ZnO NPs was characterized using different spectroscopic and microscopic instruments such as UV–Vis spectroscopy, FTIR, XRD and SEM–EDS to consider its purity, shape and crystallinity. UV–Vis analysis showed peaks in the range 305–312 nm due to synthesis of ZnO NPs. FTIR analysis showed the availability of different phytochemicals in the plant extract and synthesis of ZnO NPs at 490 cm−1. Powder XRD patterns confirmed formation of phase pure wurtzite structures of ZnO NPs. The synthesized ZnO NPs were used to remove MB dye from aqueous solution by acting as a photocatalyst and adsorbent as well as, it also showed antimicrobial activity against two gram positive (Staphylococcus epidermidis, Staphylococcus aureus) and three gram negative (Escherichia coli, Klebsiella pneumonia, Pseudomonas aeruginosa) bacteria.
Highlights
Cosmetic, food, leather, paper, plastics and textile industries use extensively different types of dyes and pigments to color their products
(Talam et al 2012) reported synthesis of ZnO NPs via precipitation method that has a size of 2.07 nm according to the equation below
Size of the synthesized nanoparticles decreased with decrease in the wavelength absorption maximum of nanoparticles
Summary
Food, leather, paper, plastics and textile industries use extensively different types of dyes and pigments to color their products. Textile industries in particular generate 100–170 L dye effluent per Kg of cloth (Mohan et al 2007). Effluents contaminated with dyes that are discharged into oceans, seas, rivers and ponds from textile factories and the like can bring disturbance to the water eco-system due to two main reasons, i.e., toxic properties of the dyes and blockage of sun light to reach the plankton in the water system. Dyes are aromatic compounds that have delocalized electron systems that can bind with a material to give color in textile factories (Velmurugan et al 2011). Effluents from textile, paper and pharmaceutical industries containing MB pollute water bodies that adversely affect the eco-system and aquatic life. A days about 700 million people of our globe have faced water scarcity for both drinking and domestic purposes due to water pollution mostly from anthropogenic activities, and it is still estimated that people faced these problem will
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