Synthesis and characterization of X (X = Ni or Fe) modified BaTiO3 for effective degradation of Reactive Red 120 dye under UV-A light and its biological activity

• Published in: Spectrochimica acta. Part A, Molecular and biomolecular spectroscopy Vol. 320; p. 124556
• Main Authors: Balu, Krishnakumar, Abisheik, T., Niyitanga, Theophile, Kumaravel, Sakthivel, Ali, Wahid, Ehtisham Khan, Mohammad, Kashif Ali, Syed, Bashiri, Abdullateef H., Zakri, Waleed, Pandiyan, V.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 05.11.2024
• Subjects: Antimicrobial activity; BaTiO3; Photodegradation; Reusability; UV-A light; Photodegradation; Antimicrobial activity; UV-A light; Reusability; BaTiO3
• ISSN: 1386-1425
• DOI: 10.1016/j.saa.2024.124556

[Display omitted] •Ni or Fe modified BaTiO3 materials were fabricated successfully.•Effectively utilized them for Reactive Red 120 (RR 120) dye degradation under UV-A light.•Compared to bare BaTiO3, both metal-modified materials efficiently degraded the RR 120 dye.•Current methodology effectively used to treat color effluents with extremely low pH levels.•The ability of the produced nanocomposites to inhibit the growth of twenty pathogens was examined. For the sustainable advancement of industrial expansion that is environmentally conscious, harmful dyes must be removed from wastewater. Untreated effluents containing colors have the potential to harm the ecosystem and pose major health risks to people, animals, and aquatic life. Here, we have fabricated Ni or Fe modified with BaTiO3 materials and effectively utilized them for Reactive Red 120 (RR 120) dye degradation under UV-A light. The synthesized materials were characterized, and their structural, and photo-physical properties were reported. Phase segregation was not present in the XRD pattern, as evidenced by the absence of secondary phase peaks linked to iron, nickel, or oxides. Low metal ion concentrations may be the cause of this, and the presence of those elements was confirmed by XPS measurements. The Raman spectra of the BaTiO3/Ni and BaTiO3/Fe samples show a widened peak at 500 cm−1, which suggests that Ni or Fe are efficiently loaded onto the BaTiO3. RR 120 dye photodegradation under UV light conditions was effectively catalyzed by BaTiO3/Fe, as evidenced by its superior performance in the UV irradiation technique over both BaTiO3 and BaTiO3/Ni. Compared to bare BaTiO3, both metal-modified materials efficiently degraded the RR 120 dye. Acidic pH facilitated the degradation process, which makes sense given that the heterogeneous photo-Fenton reaction was the mechanism of degradation along with BaTiO3 sensitization. High-acidity sewage can be dangerous and carcinogenic, and conventional biological treatment methods are not appropriate for managing it. In the current investigation, it may be used to treat color effluents with extremely low pH levels. Additionally, the ability of the produced nanocomposites to inhibit the growth of twenty pathogens was examined, along with two fungi, fifteen Gram-negative Bacilli (GNB), one Gram-positive Bacilli (GPB), and two Gram-positive Cocci (GBC).