Okeniyi, Joshua OlusegunPopoola, Abimbola Patricia IdowuOjewumi, Modupe ElizabethOkeniyi, Elizabeth ToyinIkotun, Jacob Olumuyiwa2025-03-022025-03-022018Okeniyi, J.O. et al. 2018. Tectona grandis capped silver-nanoparticle material effects on microbial strains inducing microbiologically influenced corrosion. International Journal of Chemical Engineering. 2018: 1-6. doi:10.1155/2018/71615371687-806X1687-8078 (Online)isidoc: GD1YJhttps://hdl.handle.net/10321/5819This paper investigates Tectona grandis-</jats:italic>capped silver nanoparticle material effects on the microbial strains inducing microbiologically influenced corrosion (MIC) of metals. Leaf-extract from<jats:italic> Tectona grandis</jats:italic> natural plant was used as a precursor for the synthesis of silver-nanoparticle material, which was characterised by a scanning electron microscopy having Energy Dispersion Spectroscopy (SEM + EDS) facility. Sensitivity and resistance studies by the synthesized<jats:italic> Tectona grandis </jats:italic>capped silver nanoparticle material on three Gram-positive and three Gram-negative, thus totalling six, MIC inducing microbial strains were then studied and compared with what was obtained from a control antibiotic chemical. Results showed that all the microbial strains studied were sensitive to the<jats:italic> Tectona grandis </jats:italic>capped silver nanoparticle materials whereas two strains of microbes, a Gram-positive and a Gram-negative strain, were resistant to the commercial antibiotic chemical. These results suggest positive prospects on<jats:italic> Tectona grandis</jats:italic> capped silver nanoparticle usage in corrosion control/protection applications on metallic materials for the microbial corrosion environment.</jats:p>6 pen0303 Macromolecular and Materials Chemistry0904 Chemical Engineering4004 Chemical engineeringTectona grandisArticle2025-02-1310.1155/2018/7161537