The escalating occurrence of methylene blue (MB) contamination from textile wastewater underscores the urgent demand for effective photocatalytic remediation. This study presents a depth analysis of Fe₂O₃-incorporated cobalt photocatalysts synthesized using a gelatin-modified silica hard-template method, followed by calcination at 300 and 550 °C. Structural characterization via XRD, FTIR, and EDX confirmed enhanced crystallinity and Co–O phase formation at elevated temperatures, while BET analysis revealed a reduction in surface area (123.4 to 104.5 m²/g) and pore volume (0.2236 to 0.1875 cm³/g) due to sintering and template removal. FTIR data indicated the attenuation of hydroxyl and water-related bands, suggesting decreased surface hydration at higher temperatures. Despite the decline in surface metrics, α-Fe₂O₃–Co–550 exhibited superior photocatalytic efficiency, achieving greater than 90% MB degradation under visible light, attributed to an increased cobalt content (Fe:Co≈2:1), improved phase purity, and an optimized electronic structure. Kinetic modeling revealed pseudo-first-order behavior for both samples, with α-Fe₂O₃-Co-300 showing a higher rate constant (K₁ = 0.01116 min⁻¹) yet lower overall degradation performance than α-Fe₂O₃-Co-550, highlighting the critical interplay of structural order, charge transfer efficiency, and compositional tuning enabled by hard-template synthesis for effective photocatalytic wastewater treatment.

[1] Mulushewa, Z., Dinbore, W.T., and Ayele, Y., 2021, Removal of methylene blue from textile waste water using kaolin and zeolite-x synthesized from Ethiopian kaolin, Environ. Anal. Health Toxicol., 36 (1), e2021007.

[2] Oladoye, P.O., Ajiboye, T.O., Omotola, E.O., and Oyewola, O.J., 2022, Methylene blue dye: Toxicity and potential elimination technology from wastewater, Results Eng., 16, 100678.

[3] Sarkar Phyllis, A.K., Tortora, G., and Johnson, I., 2022, “Photodegradation” in The Fairchild Books Dictionary of Textiles, Bloomsbury Publishing Inc., New York, NY, US, 340–345.

[4] Katheresan, V., Kansedo, J., and Lau, S.Y., 2018, Efficiency of various recent wastewater dye removal methods: A review, J. Environ. Chem. Eng., 6 (4), 4676–4697.

[5] Essa, W.K., 2024, Methylene blue removal by copper oxide nanoparticles obtained from green synthesis of melia azedarach: Kinetic and isotherm studies, Chemistry, 6 (1), 249–263.

[6] Krishna Moorthy, A., Govindarajan Rathi, B., Shukla, S.P., Kumar, K., and Shree Bharti, V., 2021, Acute toxicity of textile dye methylene blue on growth and metabolism of selected freshwater microalgae, Environ. Toxicol. Pharmacol., 82, 103552.

[7] Peng, X., Jiang, Y., Chen, Z., Osman, A.I., Farghali, M., Rooney, D.W., and Yap, P.S., 2023, Recycling municipal, agricultural and industrial waste into energy, fertilizers, food and construction materials, and economic feasibility: A review, Environ. Chem. Lett., 21 (2), 765–801.

[8] Ulusoy, A., Atılgan, A., Rolbiecki, R., Jagosz, B., and Rolbiecki, S., 2024, Innovative approaches for sustainable wastewater resource management, Agriculture, 14 (12), 2111.

[9] Ramesh, N., Lai, C.W., Johan, M.R.B., Mousavi, S.M., Badruddin, I.A., Kumar, A., Sharma, G., and Gapsari, F., 2024, Progress in photocatalytic degradation of industrial organic dye by utilising the silver doped titanium dioxide nanocomposite, Heliyon, 10 (24), e40998.

[10] Dostanić, J., Lončarević, D., Hadnađev-Kostić, M., and Vulić, T., 2024, Recent advances in the strategies for developing and modifying photocatalytic materials for wastewater treatment, Processes, 12 (9), 1914.

[11] 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.

[12] Rashid, R., Shafiq, I., Gilani, M.R.H.S., Maaz, M., Akhter, P., Hussain, M., Jeong, K.E., Kwon, E.E., Bae, S., and Park, Y.K., 2024, Advancements in TiO₂-based photocatalysis for environmental remediation: Strategies for enhancing visible-light-driven activity, Chemosphere, 349, 140703.

[13] Kumar, Y., Kumar, R., Raizada, P., Khan, A.A.P., Singh, A., Le, Q.V., Nguyen, V.H., Selvasembian, R., Thakur, S., and Singh, P., 2022, Current status of hematite (α-Fe₂O₃) based Z-scheme photocatalytic systems for environmental and energy applications, J. Environ. Chem. Eng., 10 (3), 107427.

[14] Keerthana, S.P., Yuvakkumar, R., Ravi, G., Kumar, P., Elshikh, M.S., Alkhamis, H.H., Alrefaei, A.F., and Velauthapillai, D., 2021, A strategy to enhance the photocatalytic efficiency of α-Fe₂O₃, Chemosphere, 270, 129498.

[15] Liu, X., Lu, Q., Zhu, C., and Liu, S., 2015, Enhanced photocatalytic activity of α-Fe₂O₃/Bi₂WO₆ heterostructured nanofibers prepared by electrospinning technique, RSC Adv., 5 (6), 4077–4082.

[16] Zhang, Y.J., He, P.Y., Zhang, Y.X., and Chen, H., 2018, A novel electroconductive graphene/fly ash-based geopolymer composite and its photocatalytic performance, Chem. Eng. J., 334, 2459–2466.

[17] Kumar, A., Trivedi, S.K., Phor, L., Malik, J., Bhargava, S., Kaushik, V., Kumar, P., and Chahal, S., 2023, Visible light activated Mg, Co co-doped hematite for effective removal of reactive red 35 from textile wastewater, Ceram. Int., 49 (23, Pt. A), 37691–37699.

[18] Subudhi, S., Mahapatra, A., Mandal, M., Das, S., Sa, K., Alam, I., Subramanyam, B.V.R.S., Raiguru, J., and Mahanandia, P., 2020, Effect of Co doping in tuning the band gap of LaFeO₃, Integr. Ferroelectr., 205 (1), 61–65.

[19] Yang, F., Yang, L., Ai, C., Xie, P., Lin, S., Wang, C. Z., and Lu, X., 2018, Tailoring bandgap of perovskite BaTiO₃ by transition metals co-doping for visible-light photoelectrical applications: A first-principles study, Nanomaterials, 8 (7), 455.

[20] Wang, J., Li, P., Zhao, Y., and Zeng, X., 2022, Nb/N co-doped layered perovskite Sr₂TiO₄: Preparation and enhanced photocatalytic degradation tetracycline under visible light, Int. J. Mol. Sci., 23 (18), 10927.

[21] Ulfa, M., Rohmah, I.S., and Anggreani, C.N., 2025, Driving photocatalytic efficiency through controlled cobalt–iron and cobalt–nickel ratios for methylene blue degradation, Bull. Chem. React. Eng. Catal., 20 (4), 607–623.

[22] do Carmo Batista, W.V.F., da Cunha, R., de Oliveira, W.L., da Cruz, T.S., Gorgulho, H.F., dos Reis Ferreira, R.A., Pereira, M.C., and Mesquita, J.P., 2025, Improved dye adsorption and photodegradation using mesoporous carbon modified with titania and magnetic nanoparticles, Results Surf. Interfaces, 19, 100532.

[23] Dziewiątka, K., Matusik, J., Trenczek-Zając, A., and Cempura, G., 2023, TiO₂-loaded nanotubular kaolin group minerals: The effect of mineral support on photodegradation of dyes as model pollutants, Appl. Clay Sci., 245, 107123.

[24] Khalaf, A., Abu-Dalo, D., and Alshamaileh, E., 2024, Synthesis, characterization, and application of Fe₂O₃ nanophotocatalyst for the treatment of various pollutants in aqueous phase: A systematic review, Sci. World J., 2024 (1), 8644322.

[25] Purnama, B., Wijayanta, A.T., and Suharyana, S., 2019, Effect of calcination temperature on structural and magnetic properties in cobalt ferrite nano particles, J. King Saud Univ. - Sci., 31 (4), 956–960.

[26] Prabhakaran, T., Mangalaraja, R.V., Denardin, J.C., and Jiménez, J.A., 2017, The effect of calcination temperature on the structural and magnetic properties of co-precipitated CoFe₂O₄ nanoparticles, J. Alloys Compd., 716, 171–183.

[27] Rostas, A.M., Suciu, R.C., Roşu, M.C., Turza, A., Cosma, D.V., Tripon, S., Fort, C.I., Danciu, V., Baia, M., Bocirnea, A., and Indrea, E., 2025, Annealing temperature, a key factor in shaping Ag-decorated TiO₂ aerogels as efficient visible-light photocatalysts, Mater. Chem. Phys., 337, 130557.

[28] Ulfa, M., and Lestari, S., 2025, Design of bi- and tri-metal oxide photocatalysts via gelatin-directed mesoporous silica hard templating for advanced dye degradation, Bull. Chem. React. Eng. Catal., 20 (4), 661–671.

[29] Jdidi, A.R., Nouira, W., Selmi, A., Drissi, N., Aissa, M., Hcini, S., and Gassoumi, M., 2025, Impact of calcination temperature on the properties and photocatalytic efficiency of Cd_0.6Mg_0.2Cu_0.2Fe₂O₄ spinel ferrites synthesized via the sol–gel method, Crystals, 15 (5), 457.

[30] Xie, T., Liu, Y., Wang, H., and Wu, Z., 2019, Synthesis of α-Fe₂O₃/Bi₂WO₆ layered heterojunctions by in situ growth strategy with enhanced visible-light photocatalytic activity, Sci. Rep., 9 (1), 7551.

[31] Deon, F., Koch-Müller, M., Rhede, D., Gottschalk, M., Wirth, R., and Thomas, S.M., 2010, Location and quantification of hydroxyl in wadsleyite: New insights, Am. Mineral., 95 (2-3), 312–322.

[32] Ulfa, M., and Rohmah, I.S., 2025, Thermal-induced structural evolution of mesoporous oxides Fe–Co–Ni for enhanced visible-light dye degradation, Next Mater., 9, 101024.

[33] Wu, L., Wang, W., Zhang, S., Mo, D., and Li, X., 2021, Fabrication and characterization of Co-doped Fe₂O₃ spindles for the enhanced photo-Fenton catalytic degradation of tetracycline, ACS Omega, 6 (49), 33717–33727.

[34] Amiruddin, E., Awaluddin, A., Rini, A.S., Umar, L., Rianna, M., Hadilala, T.P., and Putri, N., 2024, Magnetic and optical properties of a-Fe₂O₃/TiO₂ nanocomposite derived from Logas natural sand for environmental application, J. Phys. Conf. Ser., 2908 (1), 012003.

[35] Zain, M., Yasin, K.A., Haq, S., Rehman, W., Din, S.U., Shujaat, S., Syed, A., Hossain, M.K., Paray, B.A., Razzokov, J., and Samad, A., 2024, Effect of calcination temperature induced structural modifications on the photocatalytic efficacy of Fe₂O₃-ZrO₂ nanostructures: mechanochemical synthesis, RSC Adv., 14 (21), 15085–15094.

[36] Li, Y., Ren, Z., He, Z., Ouyang, P., Duan, Y., Zhang, W., Lv, K., and Dong, F., 2024, Crystallinity-defect matching relationship of g-C₃N₄: Experimental and theoretical perspectives, Green Energy Environ., 9 (4), 623–658.

[37] Zemlik, M., Białobrzeska, B., Stachowicz, M., and Hanszke, J., 2024, The influence of grain size on the abrasive wear resistance of Hardox 500 steel, Appl. Sci., 14 (24), 11490.

[38] Gareev, K.G., 2023, Diversity of iron oxides: mechanisms of formation, physical properties and applications, Magnetochemistry, 9 (5), 119.

[39] Zhao, Q., Tang, Q., Chu, H., Pan, Z., Pan, H., Zhao, S., and Li, D., 2025, Ultra-high temperature calcination of crystalline α-Fe₂O₃ and its nonlinear optical properties for ultrafast photonics, Adv. Sci., 12 (18), 2500896.

[40] Jiang, S., You, Z., and Tang, N., 2023, Effects of calcination temperature and calcination atmosphere on the performance of Co₃O₄ catalysts for the catalytic oxidation of toluene, Processes, 11 (7), 2087.

[41] Sani, A., and Dahman, Y., 2010, Improvements in the production of bacterial synthesized biocellulose nanofibres using different culture methods, J. Chem. Technol. Biotechnol., 85 (2), 151–164.

[42] Khanam, J., Hasan, M.R., Biswas, B., Ahmed, M.F., Mostofa, S., Akhtar, U.S., Hossain, M.K., Quddus, M.S., Ahmed, S., Sharmin, N., and Al-Reza, S.M., 2024, Effect of low temperature calcination on micro structure of hematite nanoparticles synthesized from waste iron source, Heliyon, 10 (24), e41030.

[43] Bullen, J.C., Saleesongsom, S., Gallagher, K., and Weiss, D.J., 2021, A revised pseudo-second-order kinetic model for adsorption, sensitive to changes in adsorbate and adsorbent concentrations, Langmuir, 37 (10), 3189–3201.