<p>Bioengineering of bimetallic oxides is a significant requirement for both social and environmental applications. In this work, bimetal oxide nanomaterials, Zinc orthotitanate Zn<sub>2</sub>TiO<sub>4</sub> was produced using a green process which utilizes natural extract of <i>Hibiscus sabdariffa</i>. More accurately, natural extract/phyto-compounds of <i>Hibiscus sabdariffa</i> was validated as an effective chelating agent at room temperature and atmospheric pressure. A variety of techniques were applied to analyse their physicochemical properties and verify the production of the Zn<sub>2</sub>TiO<sub>4</sub> nanoparticles. The XRD analysis illustrated the crystalline structure of the Zn<sub>2</sub>TiO<sub>4</sub> nanocomposites. The SEM analysis showed the morphology of the compounds Zn<sub>2</sub>TiO<sub>4</sub> to be highly porous. The EDS analysis validated the presence of elements such as Ti, and Zn while FTIR analysis indicated the existence of multiple functional groups, including O–H, C–H, C=O, Ti–O, and Zn–O bonds in the compound. The PL peaks identified at 240 and 450&#xa0;nm are attributed to the charge transfer characteristics present in the surface state of the resulting product. The single phase crystals of the bio-engineered Zn<sub>2</sub>TiO<sub>4</sub> were found to be within the nanoscale while exhibiting a significantly elevated photocatalytic efficacy in decomposing Methylene Blue reaching a threshold of about 94.1% efficacy at about 120&#xa0;min. From the electrochemistry viewpoint, the bioengineered Zn<sub>2</sub>TiO<sub>4</sub> nanomaterial demonstrated enhanced redox activity and stability, exhibiting 94.2% current retention after 20 cycles. Cyclic voltammetry (CV) studies confirmed a diffusion-controlled process, while electrochemical impedance spectroscopy (EIS) revealed a 10-fold reduction in charge transfer resistance ®<sub>ct</sub>), from 5.48 to 0.53 KΩ. This significant acceleration in electron transfer kinetics is corroborated by a nearly 2-fold increase in interfacial admittance (<i>Y</i><sub>o</sub>), indicating an expanded electroactive surface area. These results demonstrate the applicability and potential for Zn<sub>2</sub>TiO<sub>4</sub> nanomaterial in advanced electrochemical applications. From the antibacterial perspective, Zn₂TiO₄ nanomaterial showed limited activity in the agar-disc diffusion assay, with no meaningful inhibition against most tested Gram-positive and Gram-negative strains and only a marginal response against <i>K. pneumoniae</i>. These results suggest that any antibacterial potential of the Zn₂TiO₄ nanomaterial may likely to be strongly dependent on assay format, nanoparticle dispersion, contact conditions, and possible light-driven ROS generation.</p>

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Bioengineered Zn2TiO4 nanomaterial and its effective electrochemical, antibacterial and photocatalytic responses

  • A. Fall,
  • K. K. Masibi,
  • N. L. Botha,
  • KJ. Cloete,
  • R. Ahmed,
  • M. Maaza

摘要

Bioengineering of bimetallic oxides is a significant requirement for both social and environmental applications. In this work, bimetal oxide nanomaterials, Zinc orthotitanate Zn2TiO4 was produced using a green process which utilizes natural extract of Hibiscus sabdariffa. More accurately, natural extract/phyto-compounds of Hibiscus sabdariffa was validated as an effective chelating agent at room temperature and atmospheric pressure. A variety of techniques were applied to analyse their physicochemical properties and verify the production of the Zn2TiO4 nanoparticles. The XRD analysis illustrated the crystalline structure of the Zn2TiO4 nanocomposites. The SEM analysis showed the morphology of the compounds Zn2TiO4 to be highly porous. The EDS analysis validated the presence of elements such as Ti, and Zn while FTIR analysis indicated the existence of multiple functional groups, including O–H, C–H, C=O, Ti–O, and Zn–O bonds in the compound. The PL peaks identified at 240 and 450 nm are attributed to the charge transfer characteristics present in the surface state of the resulting product. The single phase crystals of the bio-engineered Zn2TiO4 were found to be within the nanoscale while exhibiting a significantly elevated photocatalytic efficacy in decomposing Methylene Blue reaching a threshold of about 94.1% efficacy at about 120 min. From the electrochemistry viewpoint, the bioengineered Zn2TiO4 nanomaterial demonstrated enhanced redox activity and stability, exhibiting 94.2% current retention after 20 cycles. Cyclic voltammetry (CV) studies confirmed a diffusion-controlled process, while electrochemical impedance spectroscopy (EIS) revealed a 10-fold reduction in charge transfer resistance ®ct), from 5.48 to 0.53 KΩ. This significant acceleration in electron transfer kinetics is corroborated by a nearly 2-fold increase in interfacial admittance (Yo), indicating an expanded electroactive surface area. These results demonstrate the applicability and potential for Zn2TiO4 nanomaterial in advanced electrochemical applications. From the antibacterial perspective, Zn₂TiO₄ nanomaterial showed limited activity in the agar-disc diffusion assay, with no meaningful inhibition against most tested Gram-positive and Gram-negative strains and only a marginal response against K. pneumoniae. These results suggest that any antibacterial potential of the Zn₂TiO₄ nanomaterial may likely to be strongly dependent on assay format, nanoparticle dispersion, contact conditions, and possible light-driven ROS generation.