Metal-based antimicrobials have the potential to profile sustainable solutions to infection care and health. In this study, we report the synthesis of rGO–ZnO hybrid nanostructures by a simple co-precipitation approach with various mass ratios of GO, and their antimicrobial potential was assessed. The structural analysis confirms the presence of a hexagonal wurtzite structure with peak shifting in hybrid nanostructures and increases in crystallite size (11–24 nm). Raman spectra revealed GO doping in the D band (1350 cm –1 ) and G band (1590 cm –1 ). Field emission scanning electron microscopy (FESEM) and transmission electron microscopy (TEM) were performed to investigate the surface morphologies of the synthesized sediments, which showed a change in the morphology of ZnO from non-uniform spherical nanoparticles to a rod-like morphology of the prepared hybrid nanostructures. RAMAN spectra revealed that the retained functional groups on rGO planes were significant in anchoring ZnO to rGO. At lowest and maximum doses of ZnO, substantial bactericidal zones ( p < 0.05) for S. aureus (1.55 and 1.95 mm) and E. coli (1.25 and 1.70 mm) were achieved accordingly. Additionally, the inhibition regions were 2.45–3.85 mm and 3.75–6.85 mm for S. aureus whereas (2.05–3.25 mm) and (2.95–3.90 mm) for E. coli at the lowest and maximum concentrations.
The ab-initio method has been applied to explore the chalcopyrite compounds HgGa2X4 (X= S, Se) structural, opto-electronics, and also thermoelectric characteristics. We attained the optimized parameters of lattice constant by employing Perdew-Burke-Ernzerhof generalized gradient approximation (PBEsol-GGA) and computed the values are approximately equal to experimental values. To calculate accurate band-gap values of both compounds, we used Trans along with Blaha reformed Becke and Johnson (TB-mBJ). Remarkably, both HgGa2X4 (X= S, Se) compounds yield a direct bandgap nature having calculated values 2.80 eV and 2.30 eV respectively, those are accurately comparable to experimental values. It also observed that the strong optical-absorption is below 3.0eV, which made both compounds favorable for solar cell device applications. In last, we make a detail investigation of thermoelectric characteristics in terms of electric and thermal conductivity, power factor and figure of merit (ZT) with the help of BoltzTrap code. To check the thermal stability of material, we accomplished the thermal parameters against temperatures.
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