Like-caviar molybdenum ferrite nanoparticles (MoFe₂O₄ NPs) have been successfully synthesized via a hydrothermal route in the presence of the negative surfactant (sodium dodecyl sulfate (SDS)). SDS acts as a template, stabilizer, and stops the aggregating process through storage. The mean crystal size of MoFe₂O₄ NPs rises with decorating it with Al₂O₃. Based on SEM analysis, the shapes of MoFe₂O₄, Al₂O₃, and their composite demonstrated like-caviar, like-brain cells, and like-grains, respectively. Al₂O₃ has been chosen to incorporate with spinel MoFe₂O₄ to make it color more light, this crucial step is necessary to enhance their optical characteristics. FTIR spectra observed the MoFe₂O₄ NPs are inverse spinel. The photo-decolorization test employs indigo carmine (IC) as a model pollutant. The quantum yields (Φ) of IC dye decolorization with studied photocatalysts are low, which may be created by quencher materials, dimerization of dye molecules, and photophysical deactivation processes (ISC process). Moreover, the photocatalytic activity of using MoFe₂O₄ raised after being decorated with alumina, which revealed an increase in the surface acidity, hydroxyl group adsorption, size, band gap, pH_pzc of MoFe₂O₄ from 2.9–3.6 to 4.2–5.9 after decorated alumina. This pH is suitable for decolorizing IC dye, which has a pH of solution equal to 5.3.

[1] Collin, F., 2019, Chemical basis of reactive oxygen species reactivity and involvement in neurodegenerative diseases, Int. J. Mol. Sci., 20 (10), 2407.

[2] Ahmed, L.M., 2021, “Bulk and Nanocatalysts Applications in Advanced Oxidation Processes” in Oxidoreductase, Eds. Mansour, M.A., IntechOpen, Rijeka, Croatia, 107–111.

[3] Sathya, K., Nagarajan, K., Carlin Geor Malar, G., Rajalakshmi, S., and Raja Lakshmi, P., 2022, A comprehensive review on comparison among effluent treatment methods and modern methods of treatment of industrial wastewater effluent from different sources, Appl. Water Sci., 12 (4), 70.

[4] Sibhatu, A.K., Weldegebrieal, G.K., Sagadevan, S., Tran, N.N., and Hessel, V., 2022, Photocatalytic activity of CuO nanoparticles for organic and inorganic pollutants removal in wastewater remediation, Chemosphere, 300, 134623.

[5] Zhang, S., Gu, P., Ma, R., Luo, C., Wen, T., Zhao, G., Cheng, W., and Wang, X., 2019, Recent developments in fabrication and structure regulation of visible-light-driven g-C₃N₄-based photocatalysts towards water purification: A critical review, Catal. Today, 335, 65–77.

[6] Jiang, L., Yuan, X., Zeng, G., Wu, Z., Liang, J., Chen, X., Leng, L., Wang, H., and Wang, H., 2018, Metal-free efficient photocatalyst for stable visible-light photocatalytic degradation of refractory pollutant, Appl. Catal., B, 221, 715–725.

[7] Chen, J., Abazari, R., Adegoke, K.A., Maxakato, N.W., Bello, O.S., Tahir, M., Tasleem, S., Sanati, S., Kirillov, A.M., and Zhou, Y., 2022, Metal–organic frameworks and derived materials as photocatalysts for water splitting and carbon dioxide reduction, Coord. Chem. Rev., 469, 214664.

[8] Akhoondi, A., Mirzaei, M., Nassar, M.Y., Sabaghian, Z., Hatami, F., and Yusuf, M., 2022, New strategies in the preparation of binary g-C₃N₄/MXene composites for visible-light-driven photocatalytic applications, Synth. Sintering, 2 (4), 151–169.

[9] Kusworo, T.D., Kumoro, A.C., Aryanti, N., Hasbullah, H., Chaesarifa, D.R.S., Fauzan, M.D., and Dalanta, F., 2023, Developing a robust photocatalytic and antifouling performance of PVDF membrane using spinel NiFe₂O₄/GO photocatalyst for efficient industrial dye wastewater treatment, J. Environ. Chem. Eng., 11 (2), 109449.

[10] Oyewo, O.A., Elemike, E.E., Onwudiwe, D.C., and Onyango, M.S., 2020, Metal oxide-cellulose nanocomposites for the removal of toxic metals and dyes from wastewater, Int. J. Biol. Macromol., 164, 2477–2496.

[11] Weber, J.N., Minner-Meinen, R., Behnecke, M., Biedendieck, R., Hänsch, V.G., Hercher, T.W., Hertweck, C., van den Hout, L., Knüppel, L., Sivov, S., Schulze, J., Mendel, R.R., Hänsch, R., and Kaufholdt, D., 2023, Moonlighting Arabidopsis molybdate transporter 2 family and GSH-complex formation facilitate molybdenum homeostasis, Commun. Biol., 6 (1), 801.

[12] Pal, S., Sarkar, A., Satra, J., Mondal, P., Ray, P., Srivastava, D.N., Adhikary, B., and Show, B., 2022, Tetraphenylporphyrin decorated Bi₂MoO₆ nanocomposite: Its twin affinity of oxygen reduction reaction and electrochemical detection of 4-nitrophenol, Inorg. Chem., 61 (44), 17402–17418.

[13] Mohmoud, A., Rakass, S., Oudghiri Hassani, H., Kooli, F., Abboudi, M., and Ben Aoun, S., 2020, Iron molybdate Fe₂(MoO₄)₃ nanoparticles: Efficient sorbent for methylene blue dye removal from aqueous solutions, Molecules, 25 (21), 5100.

[14] Wu, Y.Y., Song, B.Y., Zhang, X.F., Deng, Z.P., Huo, L.H., and Gao, S., 2021, Microtubular α-Fe₂O₃/Fe₂(MoO₄)₃ heterostructure derived from absorbent cotton for enhanced ppb-level H₂S gas-sensing performance, J. Alloys Compd., 867, 158994.

[15] Qiu, Y., Li, G., Zhou, H., Zhang, G., Guo, L., Guo, Z., Yang, R., Fan, Y., Wang, W., Du, Y., and Dang, F., 2023, Highly stable garnet Fe₂Mo₃O₁₂ cathode boosts the lithium–air battery performance featuring a polyhedral framework and cationic vacancy concentrated surface, Adv. Sci., 10 (12), 2300482.

[16] Nisar, J., Hassan, S., Khan, M.I., Iqbal, M., Nazir, A., Sharif, A., and Ahmed, E., 2020, Hetero-structured iron molybdate nanoparticles: Synthesis, characterization and photocatalytic application, Int. J. Chem. Reactor Eng., 18 (2), 20190123.

[17] Zhang, X., Liu, W., Gao, T., Cao, D., Che, X., Zhou, S., Shang, J., and Cheng, X., 2023, A novel iron molybdate photocatalyst with heterojunction-like band gap structure for organic pollutant degradation by activation of persulfate under simulated sunlight irradiation, Environ. Sci. Pollut. Res., 30 (18), 53157–53176.

[18] Seevakan, K., Manikandan, A., Devendran, P., Antony, S.A., and Alagesan, T., 2016, One-pot synthesis and characterization studies of iron molybdenum mixed metal oxide (Fe₂(MoO₄)₃) nano-photocatalysts, Adv. Sci., Eng. Med., 8 (7), 566–572.

[19] Zou, S., Luo, J., Lin, Z., Fu, P., and Chen, Z., 2018, Acetone gas sensor based on iron molybdate nanoparticles prepared by hydrothermal method with PVP as surfactant, Mater. Res. Express, 5 (12), 125013.

[20] Liu, L., Zhao, J., Wang, S., Zhang, B., Yang, J., and Liu, H., 2023, Supercritical hydrothermal synthesis of nano-zirconia: Reaction path and crystallization mechanisms of different precursors, E3S Web Conf., 406, 01025.

[21] Obaid, A., and Ahmed, L., 2021, One-step hydrothermal synthesis of α-MoO₃ nano-belts with ultrasonic assist for incorporating TiO₂ as a nanocomposite, Egypt. J. Chem., 64 (10), 5725–5734.

[22] Mikhaylov, V., Krivoshapkina, E., Belyy, V., Isaenko, S., Zhukov, M., Gerasimov, E., and Krivoshapkin, P., 2019, Magnetic mesoporous catalytic and adsorption active Fe-Al₂O₃ films, Microporous Mesoporous Mater., 284, 225–234.

[23] Kılınç, D., and Şahin, Ö., 2019, Al₂O₃ based Co-Schiff Base complex catalyst in hydrogen generation, Int. J. Hydrogen Energy, 44 (53), 28391–28401.

[24] Abd Zaid, A.A., Ahmed, L.M., and Mohammad, R.K., 2022, Synthesis of inverse spinel nickel ferrite like-broccoli nanoparticle and thermodynamic study of photo-decolorization of alkali blue 4B dye, J. Nanostruct., 12 (3), 697–710.

[25] Sharma, A.K., and Lee, B.K., 2016, Surfactant-aided sol-gel synthesis of TiO₂–MgO nanocomposite and their photocatalytic azo dye degradation activity, J. Compos. Mater., 54 (12), 1561–1570.

[26] Kadhim, H., Ahmed, L., and AL-Hachamii, M., 2022, Facile synthesis of spinel CoCr₂O₄ and its nanocomposite with ZrO₂: Employing in photo‐catalytic decolorization of Fe(II)-(luminol-tyrosine) complex, Egypt. J. Chem., 65 (1), 481–488.

[27] Tsegaye, F., Taddesse, A.M., Teju, E., and Aschalew, M., 2020, Preparation and sorption property study of Fe₃O₄/Al₂O₃/ZrO₂ composite for the removal of cadmium, lead and chromium ions from aqueous solutions, Bull. Chem. Soc. Ethiop., 34 (1), 105–121.

[28] Saeed, S.I., Attol, D.H., Eesa, M.T., and Ahmed, L.M., 2023, Zinc oxide-mediated removal and photocatalytic treatment of direct orange 39 dye as a textile dye, AIP Conf. Proc., 2414, 050021.

[29] Jaafar, M.T., and Ahmed, L.M., 2020, Reduced the toxicity of acid black (nigrosine) dye by removal and photocatalytic activity of TiO₂ and studying the effect of pH, temperatue, and the oxidant agents, AIP Conf. Proc., 2290 (1), 030034.

[30] Hussain, Z.A., Fakhri, F.H., Alesary, H.F., and Ahmed, L.M., 2020, ZnO based material as photocatalyst for treating the textile anthraquinone derivative dye (dispersive blue 26 dye): Removal and photocatalytic treatment, J. Phys.: Conf. Ser., 1664 (1), 12064.

[31] Saeed, S.I., Taresh, B.H., Ahmed, L.M., Haboob, Z.F., Hassan, S.A., and Jassim, A.A.A., 2021, Insight into the oxidant agents effect of removal and photo-decolorization of vitamin B₁₂ solution in drug tablets using ZrO₂, J. Chem. Health Risks, 11 (4), 393–402.

[32] Ramachandran, K., Chidambaram, S., Baskaran, B., Muthukumarasamy, A., and Lawrence, J.B., 2017, Investigations on structural, optical and magnetic properties of solution-combustion-synthesized nanocrystalline iron molybdate, Bull. Mater. Sci., 40 (1), 87–92.

[33] Loomba, S., Khan, M., Haris, M., Mousavi, S., Zavabeti, A., Xu, K., Tadich, A., Thomsen, L., McConville, C.F., Li, Y., Walia, S., and Mahmood, N., 2023, Nitrogen‐doped porous nickel molybdenum phosphide sheets for efficient seawater splitting, Small, 19 (18), 2207310.

[34] Bekakria, H., Bendjeffal, H., Djebli, A., Mamine, H., Metidji, T., and Benrdjem, Z., 2021, Heterogeneous sono-photo-Fenton degradation of methyl violet 10B using Fe₂O₃-Al₂O₃-Ga₂O₃ as a new photocatalyst, Inorg. Nano-Met. Chem., 51 (12), 1759–1774.

[35] Yin, C., Li, S., Liu, L., Huang, Q., Zhu, G., Yang, X., and Wang, S., 2022, Structure-tunable trivalent Fe-Al-based bimetallic organic frameworks for arsenic removal from contaminated water, J. Mol. Liq., 346, 117101.

[36] Casillas, J.E., Campa-Molina, J., Tzompantzi, F., Carbajal Arízaga, G.G., López-Gaona, A., Ulloa-Godínez, S., Cano, M.E., and Barrera, A., 2020, Photocatalytic degradation of diclofenac using Al₂O₃-Nd₂O₃ binary oxides prepared by the sol-gel method, Materials, 13 (6), 1345.

[37] Ali, S., Ali, M., and Ahmed, L., 2021, Hybrid phosphotungstic acid-dopamine (PTA-DA) like-flower nanostructure synthesis as a furosemide drug delivery system and kinetic study of drug releasing, Egypt. J. Chem., 64 (10), 5547–5553.

[38] Hasan Taresh, B., Hadi Fakhri, F., and Ahmed, L.M., 2022, Synthesis and characterization of CuO/CeO₂ nanocomposites and investigation their photocatalytic activity, J. Nanostruct., 12 (3), 563–570.

[39] Sharifi, S., Yazdani, A., and Rahimi, K., 2020, Incremental substitution of Ni with Mn in NiFe₂O₄ to largely enhance its supercapacitance properties, Sci. Rep., 10 (1), 10916.

[40] Mursyalaat, V., Variani, V.I., Arsyad, W.O.S., and Firihu, M.Z., 2023, The development of program for calculating the band gap energy of semiconductor material based on UV-Vis spectrum using delphi 7.0., J. Phys.: Conf. Ser., 2498 (1), 012042.

[41] Yuniar, Y., Agustina, T., Faizal, M., and Hariani, P.L., 2023, Synthesis and characterization of ZnO/MnFe₂O₄ nanocomposites for degrading cationic dyes, J. Ecol. Eng., 24 (4) 252–263.

[42] Hariani, P.L., Said, M., Salni, S., Aprianti, N., and Naibaho, Y.A.L.R., 2021, High efficient photocatalytic degradation of methyl orange dye in an aqueous solution by CoFe₂O₄-SiO₂-TiO₂ magnetic catalyst, J. Ecol. Eng., 23 (1), 118–128.

[43] Kefeni, K.K., and Mamba, B.B., 2020, Photocatalytic application of spinel ferrite nanoparticles and nanocomposites in wastewater treatment: Review, Sustainable Mater.Technol., 23, e00140.

[44] Navajas, A., Reyero, I., Jiménez-Barrera, E., Romero-Sarria, F., Llorca, J., and Gandía, L.M., 2020, Catalytic performance of bulk and Al₂O₃-supported molybdenum oxide for the production of biodiesel from oil with high free fatty acids content, Catalysts, 10 (2), 158.

[45] Singh, B., Singh, P., Siddiqui, S., Singh, D., and Gupta, M., 2022, Wastewater treatment using Fe-doped perovskite manganites by photocatalytic degradation of methyl orange, crystal violet and indigo carmine dyes in tungsten bulb/sunlight, J. Rare Earths, 41 (9), 1311–1322.

[46] Hossain, M.S., Tuntun, S.M., Bahadur, N.M., and Ahmed, S., 2022, Enhancement of photocatalytic efficacy by exploiting copper doping in nano-hydroxyapatite for degradation of Congo red dye, RSC Adv., 12 (52), 34080–34094.

[47] Wang, L., Deng, J., Jiang, M., Zhen, C., Li, F., Li, S., Bai, S., Zhang, X., and Zhu, W., 2023, Arene–perfluoroarene interactions in molecular cocrystals for enhanced photocatalytic activity, J. Mater. Chem. A, 11 (21), 11235–11244.

[48] Pavel, M., Anastasescu, C., State, R.N., Vasile, A., Papa, F., and Balint, I., 2023, Photocatalytic degradation of organic and inorganic pollutants to harmless end products: Assessment of practical application potential for water and air cleaning, Catalysts, 13 (2), 380.

[49] Singh, M., Kumar, A., and Krishnan, V., 2020, Influence of different bismuth oxyhalides on the photocatalytic activity of graphitic carbon nitride: A comparative study under natural sunlight, Mater. Adv., 1 (5), 1262–1272.

[50] Ahmed, S., 2004. Photo electrochemical study of ferrioxalate actinometry at a glassy carbon electrode, J. Photochem. Photobiol., A, 161 (2-3), 151–154.

[51] Kamran, M., Morsy, M., Kandiel, T., and Iali, W., 2022, Semi-automated EPR system for direct monitoring the photocatalytic activity of TiO₂ suspension using TEMPOL model compound, Photochem. Photobiol. Sci., 21 (12), 2071–2083.

[52] Megatif, L., Dillert, R., and Bahnemann, D.W., 2020, Determination of the quantum yield of a heterogeneous photocatalytic reaction employing a black body photoreactor, Catal. Today, 355, 698–703.

[53] Qureshi, M., and Takanabe, K., 2017, Insights on measuring and reporting heterogeneous photocatalysis: Efficiency definitions and setup examples, Chem. Mater., 29 (1), 158–167.

[54] Ahmed, L.M., Saaed, S.I., and Marhoon, A.A., 2018, Effect of oxidation agents on photo-decolorization of vitamin B₁₂ in the presence of ZnO/UV-A system, Indones. J. Chem., 18 (2), 272–278.

[55] Cardoso, I.M.F., Cardoso, R.M.F., and da Silva, J.C.G.E., 2021, Advanced oxidation processes coupled with nanomaterials for water treatment, Nanomaterials, 11 (8), 2045.

[56] Putri, R.A., Safni, S., Jamarun, N., Septiani, U., Kim, M.K., and Zoh, K., 2019, Kinetics studies on photodegradation of methyl orange in the presence of C-N-codoped TiO₂ catalyst, Egypt. J. Chem., 62 (Part 2), 563–575.

[57] Kazm, K.H., and Najim, S.T., 2022, Study kinetic reaction and removal of indigo carmine dye in aqueous solutions by direct electrochemical oxidation, IOP Conf. Ser.: Earth Environ. Sci., 1002 (1), 012005.

[58] Ortiz, E., Gómez-Chávez, V., Cortés-Romero, C.M., Solís, H., Ruiz-Ramos, R., and Loera-Serna, S., 2016, Degradation of indigo carmine using advanced oxidation processes: Synergy effects and toxicological study, J. Environ. Prot., 7 (12), 1693–1706.

[59] Zaouak, A., Noomen, A., and Jelassi, H., 2018, Gamma-radiation induced decolorization and degradation on aqueous solutions of Indigo Carmine dye, J. Radioanal. Nucl. Chem., 317 (1), 37–44.