Industrial dye effluent degradation and in-vitro biological characteristics of MgO NPs anchored few layered g-C3N4 nanoribbons

Abstract

In recent years, contaminated water consumption by humans and animals are lead to various types of diseases and environmental pollutant. Especially textile dye effluents are the highest contaminants in water bodies than any other industries. This article reports a green process for synthesizing MgO nanoparticles supported by the exfoliated g-C3N4 nano composites for dye effluent treatment. The cubic and hexagonal phase structure was achieved for synthesized MgO NPs and E-GCN, respectively, with spherical and curled ribbon-like morphology. The specific surface area was measured as 70.48, 54.22, and 79.11 m2/g, respectively, for MgO NPs, E-GCN, and MgO/E-GCN nanocomposite. Similarly, corresponding optical properties were achieved with an energy gap of 3.42, 2.48, and 2.78 eV. XPS analysis confirms the formation of MgO/E-GCN nanocomposite by detecting their characteristic elemental peaks. The bioactivities including antibacterial, turbidimetric, and antioxidant efficacy, were also investigated. Thus, the MgO/E-GCN nanocomposites was exhibitd greater susceptibility against pathogenic bacteria due to its production of high reactive oxygen species. Further, the catalysts were used to degrade cationic dye (Crystal Violet) and anionic dye (Eosin Yellow) under sunlight exposure. The photocatalytic efficiency of MgO/E-GCN nanocomposite was highly influenced towards CV (98.9 %) and EY (97.33 %) dye degradation, because of its high surface area with active UV–Visible region. Therefore, the combination of naturally inspired MgO NPs and morphologically modified E-GCN nanocomposites are being a sustainable material development for environmental remediation and biological applications.