مطالعات علوم محیط زیست

مطالعات علوم محیط زیست

سنتز فتوکاتالیست SnO2 نانوساختار به روش سالوترمال و ارزیابی عملکرد آن در مقایسه با ZnO جهت تخریب آلاینده متیل اورانژ تحت تابش نور خورشید

نوع مقاله : مقاله پژوهشی

نویسندگان
پریسا صادقپور 1
محمد حقیقی 2
مریم شعبانی 3
1 استادیار مهندسی شیمی، دانشکده فنی و مهندسی، گروه مهندسی شیمی، دانشگاه ارومیه، ارومیه، ایران
2 استاد مهندسی شیمی، دانشکده مهندسی شیمی، دانشگاه صنعتی سهند، شهر جدید سهند، تبریز، ایران
3 محقق پسادکتری، دانشکده مهندسی شیمی، دانشگاه صنعتی سهند، شهر جدید سهند، تبریز، ایران
10.22034/jess.2025.492253.2315
چکیده
در این پژوهش، فتوکاتالیست نانوساختار SnO2 بطور موفقیت آمیزی با استفاده از روش سالوترمال سنتز گردید. بعلاوه، عملکرد فتوکاتالیستی SnO2 سنتز شده در جهت تخریب آلاینده متیل اورانژ تحت تابش نور شبیه سازی شده به نور خورشید مورد ارزیابی قرار گرفته و با فعالیت فتوکاتالیستی ZnO سنتز شده به روش مرسوم رسوبی مقایسه شد. برای تعیین خصوصیات فیزیکی، شیمیایی و نوری فتوکاتالیست‌های سنتزی از آنالیزهای XRD، FESEM، EDX-dot mapping، BET-BJH، DRS و FTIR استفاده شد. آنالیز BET-BJH نشان داد که نانوفتوکاتالیست‌های سنتزی از ساختارهای مزوحفره برخوردارند. با توجه به آنالیز DRS، توانایی جذب نور در ناحیه مرئی و فرابنفش، توسط نانوفتوکاتالیست‌های سنتز شده تأیید شد. همچنین، نتایج بدست آمده نشان داد که فتوکاتالیست SnO2 به جهت داشتن خصوصیات مطلوب نوری و ساختاری بیشترین بازده (%6/91) و سریعترین سرعت واکنش ( min-1 037/0k=) را در حذف آلاینده‌ی رنگی متیل اورانژ از آب دارا می‌باشد. بهبود عملکرد فتوکاتالیستی SnO2 توسط قابلیت جذب نور در محدوده مناسب و تولید موثر حامل‌های بار توجیه‌پذیر می‌باشد. از سوی دیگر، مکانیسم‌های واکنش نیز جهت تخریب فتوکاتالیستی متیل اورانژ با استفاده از فتوکاتالیست‌های ZnO و SnO2 نانوساختار پیشنهاد شدند.
کلیدواژه‌ها
SnO2 نانوساختار
اکسید روی
متیل اورانژ
نور خورشید
تصفیه آب

عنوان مقاله English

Synthesis of Nano-Structured SnO2 photocatalyst via Solvothermal Method and its Performance Evaluation for Degradation of Methyl Orange under Solar-light in Comparison with ZnO

نویسندگان English

Parisa Sadeghpour 1
Mohammad Haghighi 2
Maryam Shabani 3
1 Assistant Professor of Chemical Engineering, Chemical Engineering Department, Faculty of Engineering, Urmia University, Urmia, Iran
2 Professor of Chemical Engineering, Chemical Engineering Faculty, Sahand University of Technology, Sahand new town, Tabriz, Iran
3 PostDoc Researcher, Chemical Engineering Faculty, Sahand University of Technology, Sahand new town, Tabriz, Iran
چکیده English

In this research, the nano-structured SnO2 photocatalyst was successfully synthesized using the solvothermal method. Moreover, its photocatalytic activity for the degradation of methyl orange under simulated solar light irradiation was investigated and compared with ZnO photocatalytic activity prepared via a simple precipitation route. To determine the physical, chemical and optical characteristics of prepared photocatalysts, XRD, FESEM, EDX-dot mapping, BET-BJH, DRS and FTIR were used. The BET-BJH analysis demonstrated that the synthesized nanophotocatalysts have mesopores structures. According to the DRS analysis, the ability of the light absorption in the visible and violet regions by synthesized nanophotocartalysts was proved. Also, the results revealed that SnO2 owning to its proper optical and structural properties had the highest efficiency (91.6%) and reaction rate (k=0.037 min-1) on the photo-degradation of methyl orange from water. The enhanced photocatalytic performance of SnO2 was ascribed to the suitable light absorption capability and effective production of charge carriers. Furthermore, the reaction mechanisms were suggested for the photo-degradation of methyl orange over ZnO and SnO2 photocatalysts.

Introduction

One of the major environmental challenges is water pollution. Dyes are considered one of the most important and abundant pollutants of water resources. Organic dyes such as acid orange 7, methylene blue, methyl orange, and so on are the materials that can enter water sources through industrial pollutants. Advanced oxidation processes (AOPs) hold great promise in removing organic contaminants. Among the AOP processes, photocatalytic oxidation has been demonstrated as an efficient technology for the distracting organic dyes. In the photocatalytic purification method, electron-hole pairs are generated by light photons which also lead to strong oxidants such as hydroxyl radicals •)OH) and holes. During the past forty years, various photocatalysts have been used in water treatment. TiO2 and ZnO are widely used for environmental applications due to their advantages such as nontoxicity, cheapness, and physical and chemical stability. On the other hand, the SnO2 semiconductor with the unique band gap and properly layered structure can degrade organic pollutants from waste water under sunlight irradiation. Therefore, according to the existing research gap in the field of photocatalytic performance of SnO2, the nanostructured SnO2 photocatalyst was synthesized by the solvothermal method, and its photocatalytic performance was compared with the synthesized ZnO for the degradation of methyl orange pollutant.

Materials and methods
Firstly, ZnO was prepared by using the precipitation method. In a typical procedure, a weighted amount of Zn(NO3)2.6H2O was dissolved in deionized water under stirring. Afterward, 1 M sodium hydroxide was dropped into the prepared solution to adjust the pH value to 10. After mixing the solution for 2 hours at room temperature, the suspension was filtered and washed with distilled water and dried at 110 °C for 12 h.
Moreover, the SnO2 photocatalyst was synthesized via the solvothermal method. A desired value of SnF2 was dissolved in the solution of deionized water and ethanol. In a second step for obtaining the form of SnO2, hydrochloric acid was poured dropwise into the prepared solution until the pH reached 1under mixing conditions for 30 min. Then, the solution was heated at 180 °C for 6 h in a stainless-steel autoclave. After cooling to ambient temperature, the resulting product was washed with distilled water and dried at 110 °C for 12 h.

Results and discussion
The results from the XRD and FESEM analyses demonstrated the production of highly crystallized ZnO nanopowder with more agglomerated particles in comparison with SnO2. Moreover, the surface of the SnO2 nanophotocatalyst had a uniform distribution of particles. EDX dot-mapping illustrated the uniform distribution of all elements for SnO2 which could be effective for photocatalytic activity. The SnO2 nanophotocatalyst also had a higher surface area in comparison with ZnO, resulting in efficient photocatalytic performance due to providing more active sites for degradation. The band gap values of ZnO and SnO2 were found to be 3.14 and 2.85 eV, respectively. The obtained observations of the FTIR spectrum were in agreement with the results of XRD analysis and confirmed the formation of crystalline structures of ZnO and SnO2 nanophotocatalysts. The photocatalytic activity of samples was evaluated for degradation of 10 mg/L MO under simulated solar light irradiation. The degradation efficiency showed that the high photocatalytic degradation of MO was achieved by SnO2 after 90 min. This observation can be attributed to the superior structural and optical properties of SnO2.

Conclusion
One of the main challenges of photocatalytic performance is to achieve a photocatalyst with high activity and suitable properties under sunlight irradiation. For this purpose, the nanophotocatalysts of ZnO and SnO2 were successfully synthesized and their photocatalytic performance for the removal of MO was evaluated under simulated sunlight irradiation. The results of XRD, FESEM, EDX dot-mapping and BET-BJH showed that using the solvothermal method for SnO2 synthesis led to a high specific surface area, uniform distribution of elements and particles and low surface roughness. Also, DRS analysis indicated an increment in the range of light absorption for SnO2. The nanophotocatalysts of SnO2 represented higher photocatalytic efficiency (91.6%) after 75 min. The existence of suitable photocatalytic properties for SnO2 semiconductor including narrow band gap, improved positions of conduction and valence bands, low recombination rate of charge carriers and the accessibility of active sites caused the superior photocatalytic performance for this sample.
he photocatalytic process is carried out to generate highly potent oxidizing species, electron-hole, on the surface of semiconductor photocatalysts. Under simulated sunlight irradiation (315 nm < λ), the energy of electrons in the valence band is elevated to the conduction band, which is at a higher energy level. This results in the formation of positive holes in the valence band, and each of the created centers can initiate a series of chain reactions on the surface of photocatalysts. Both the valence and conduction bands of ZnO nanophotocatalyst are higher than these energy levels for the SnO2 nanophotocatalyst. Based on the presented results, it seems that ZnO and SnO2 nanophotocatalysts use almost similar mechanisms to remove methyl orange pollutant. However, the results of the performance evaluation of these nanophotocatalysts showed that they have different efficiencies in removing the methyl orange color pollutant. This event can be attributed to the diverse electronic positions of the valence and conduction layers for ZnO and SnO2 nanophotocatalysts, different energy gaps responsible for creating and separating electrons and holes, the ability to absorb higher wavelength limits, the number of active sites available, and the lower surface roughness for SnO2 nanophotocatalysts.

کلیدواژه‌ها English

Nanostructured SnO2
Zinc Oxide
Methyl Orange
Solar Light
Water Treatment
1.         Abbasi, Asl E., Haghighi, M., Talati, A. 2024. Enhanced solar-driven photocatalytic degradation of organic dyes using sono-dispersed mesoporous MgAl2O4 over carbon based materials, Journal of the Taiwan Institute of Chemical Engineers, Vol. 162, P. 105627.
2.       Menon, K., Lopis. AD., Choudhari, KS., Kulkarni. B., Maradur, S., Kulkarni, SD. 2025. Scavenger-free solar photocatalytic degradation of Textile Dyes and Antibiotics using magnetically separable bi-junctional photocatalyst, Materials Research Bulletin, Vol. 181, P. 113074.
3.       Sadeghpour, P., Haghighi, M., Haghighi, A., Shabani, M. 2022. Ultrasonic-promoted growth of staggered heterostructured tin(II) oxide nanoparticles on bulk carbon nitride nanolayer: Activated in solar spectrum with enhanced photocatalytic treatment of dyes effluents, Solar Energy, Vol. 241, P. 437-451.
4.       Osman, MSS., Alias, NH., Jamaluddin, NS., Abdullah, N., Othman, NH., et al. 2022. Progress on emerging photocatalysts for treatment of dyes in wastewater: a review, Desalination and Water Treatment , Vol. 257, P. 270-289.
5.       Karimi, F., Zare, N., Jahanshahi, R., Arabpoor, Z., Ayati, A., et al. 2023. Natural waste-derived nano photocatalysts for azo dye degradation,  Environmental Research , Vol. 238, P. 117202.
6.       Mohseni, N., Haghighi, M., Shabani, M. 2022. Bimetallic Co2+Cr3+LDH anchored AgCl as excellent solar-light-responsive Ag-decorated type II nano-heterojunction for photodegradation of various dyes, Process Safety and Environmental Protection, Vol. 168, P. 668-688.
7.       Jamil, T. 2024. Role of advance oxidation processes (AOPs) in textile wastewater treatment: A critical review, Desalination and Water Treatment , Vol. 318, P. 100387.
8.       Kurian, M. 2021. Advanced oxidation processes and nanomaterials -a review, Cleaner Engineering and Technology, Vol  2, P. 100090.
9.       Chen, Y-d., Duan, X., Zhou, X., Wang, R., Wang, S., et al. 2021. Advanced oxidation processes for water disinfection: Features, mechanisms and prospects, Chemical Engineering Journal, Vol. 409, P. 128207.
10.   Shabani, M., Haghighi, M., Kahforoushan, D. 2018. One-pot combustion fabrication of grain-like mesoporous intra-heterostructure BixOyClz nanophotocatalyst with substantial solar-light-driven degradation of antibiotic ofloxacin: influence of various fuels, Catalysis Science & Technology, Vol. 8, P. 4052-469.
11.   Yin, Q., Wang, Y., Li, W., Wei, C., Chen, Y., et al. 2024. Highly efficient removal of contaminant from typical dye wastewater by using individual AOPs-A/O processes: Design, performance, and mechanism, Journal of Environmental Chemical Engineering, Vol. 12, P. 113103.
12.   Hama, Aziz KH., Miessner, H., Mueller, S., Kalass, D., Moeller, D., et al. 2017. Degradation of pharmaceutical diclofenac and ibuprofen in aqueous solution, a direct comparison of ozonation, photocatalysis, and non-thermal plasma, Chemical Engineering Journal, Vol. 313, P. 1033-1041.
13.   Pawar, RC., Cho, D., Lee, CS. 2013. Fabrication of nanocomposite photocatalysts from zinc oxide nanostructures and reduced graphene oxide, Current Applied Physics, Vol 13, P. S50-S7.
14.   Shahidi, D., Roy, R., Azzouz, A. 2015. Advances in catalytic oxidation of organic pollutants–Prospects for thorough mineralization by natural clay catalysts, Applied Catalysis B: Environmental, Vol. 174, P. 277-92.
15.   Qi, F., Chu, W., Xu, B. 2015. Ozonation of phenacetin in associated with a magnetic catalyst CuFe2O4: the reaction and transformation, Chemical Engineering Journal, Vol. 262, P. 552-562.
16.   Okpara, EC., Wojuola, OB., Quadri, TW., Banks, CE. 2024. An overview of advanced oxidation processes using copper-based catalytic degradation of organic pollutants in water, Applied Materials Today, Vol. 36, P. 102053.
17.   Wang, J., Zhuan, R. 2020. Degradation of antibiotics by advanced oxidation processes: An overview, Science of The Total Environment, Vol. 701, P. 135023.
18.   Yosefi, L., Haghighi, M. 2019. Sequential Precipitation Design of p-BiOCl-p-Mn3O4 Binary Semiconductor Nanoheterojunction with Enhanced Photoactivity for Acid Orange 7 Removal from Water, Ceramics International, Vol. 45, P. 8248-8250.
19.   Ebrahimi, A., Haghighi, M., Shabani, M. 2024. Design of novel solar-light-induced KBi6O9I/Ag–AgVO3 nanophotocatalyst with Ag-bridged Z-scheme charge carriers separation and boosted photo-elimination of hospital effluents, Environmental Pollution, Vol. 346, P. 123584.
20.     Rabbani, M.,  Rahimi, R., Abbasi, E. 2017. Synthesis of BiFeO3 nanostructures via microwave-assisted    combustion method and photocatalytic study of it for photoderadation of methyl orange, Journal of Environmental Science Studies, Vol. 2, P. 492-498.
21.   Esmaeili, M., Haghighi, M., Shabani, M., Gorouhi, N. 2024. Self-assembled nano-disk architecture of broccoli-shaped Bi4V2O11 anchored with Ag-Ag3O4 co-catalyst as 3D/0D solar-light-driven Z-scheme photocatalyst: Textile industry effluents remediation, Journal of Environmental Chemical Engineering, Vol. 12, P. 11634.
22.   Yu, Y., Ming, H., He, D., Li, J., Jin, Y., et al. 2023. V2O5-based photocatalysts for environmental improvement: Key challenges and advancements, Journal of Environmental Chemical Engineering, Vol. 11, P. 111243.
23.         Chankhanittha, T., Komchoo, N., Senasu, T., Piriyanon, J., Youngme, S., et al. 2021. Silver decorated ZnO photocatalyst for effective removal of reactive red azo dye and ofloxacin antibiotic under solar light irradiation, Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 626, P. 127034.
24.   Rahmanifard, R., Abbasi, E., Rabbani, M. 2018. Photodegradation of pollution by dandelion-like of CuO     microspheres synthesized by coprecipitation, Journal of Environmental Science Studies, Vol. 3, P. 721-728.
25.   Bhunia, SK., Jana, NR. 2014. Reduced Graphene Oxide-Silver Nanoparticle Composite as Visible Light Photocatalyst for Degradation of Colorless Endocrine Disruptors, ACS Applied Materials & Interfaces, Vol.  6, P. 20085-20092.
26.   Di, Paola A., García-Lopez, E., Marcì, G., Palmisano, L. 2012. A survey of photocatalytic materials for environmental remediation, Journal of Hazardous Materials, Vol.  211-212, P. 3-29.
27.   Sun, H., Liu, S., Liu, S., Wang S. 2014. A comparative study of reduced graphene oxide modified TiO2, ZnO and Ta2O5 in visible light photocatalytic/photochemical oxidation of methylene blue, Applied Catalysis B: Environmental, Vol. 146, P. 162-168.
28.   El-Kemary, M., El-Shamy, H., El-Mehasseb I. 2010. Photocatalytic degradation of ciprofloxacin drug in water using ZnO nanoparticles, Journal of Luminescence - J luminesc, Vol. 130, P. 2327-2331.
29.   Feng, L., He, R., Li, H., Wang, J., Chen, S., et al. 2023. An efficient pretreatment method based on AgNPs-doped SnO2 photocatalyst for the accurate detection of heavy metals in organic-rich water samples, Chemosphere, Vol. 344, P. 140270.
30.   Kumari, H., Sonia, Chahal S., Suman., Kumar, P., et al. 2023. Photocatalytic Degradation of RB dye via Cerium substituted SnO2 Photocatalysts, Materials Science and Engineering: B, Vol. 296, P. 116654.
31.   Kaur, H., Bhatti, HS., Singh, K. 2020. Pr doped SnO2 nanostructures: Morphology evolution, efficient photocatalysts and fluorescent sensors for the detection of Cd2+ ions in water, Journal of Photochemistry and Photobiology A: Chemistry, Vol. 388, P. 112144.
32.   Iqbal, K., Ikram, M., Afzal, M., Ali, S. 2018. Efficient, low-dimensional nanocomposite bilayer CuO/ZnO solar cell at various annealing temperatures, Materials for Renewable and Sustainable Energy, Vol. 7, P. 4.
33.   Jung, HJ., Koutavarapu, R., Lee, S., Kim, JH., Choi, HC., Choi, MY. 2018. Enhanced photocatalytic activity of Au-doped Au@ZnO core-shell flower-like nanocomposites, Journal of Alloys and Compounds, Vol. 735, P. 2058-2066.
34.   Bose, C., Kalpana, D., Paramasivam, T., Ramasamy, S. 2002. Synthesis and Characterization of Nanocrystalline SnO2 and Fabrication of Lithium Cell Using Nano-SnO2, Journal of Power Sources, Vol. 107, P. 138-41.
35.   Ristic, M., Ivanda, M., Popovic, S., Music, S. 2002. Dependence of Nanocrystalline SnO2 Particle Size on Synthesis Route, Journal of Non-Crystalline Solids, Vol. 303.
36.   Shabani, M., Haghighi, M., Kahforoushan, D., Haghighi, A. 2019. Sono-solvothermal hybrid fabrication of BiOCl-Bi24O31Cl10/rGO nano-heterostructure photocatalyst with efficient solar-light-driven performance in degradation of fluoroquinolone antibiotics, Solar Energy Materials and Solar Cells, Vol. 193, P. 335-350.
37.   Sokhansanj, A., Haghighi, M., Shabani, M. 2024. Developing the novel model for kinetics and mass transfer in sun-light-driven photodegradation of malachite green over Bi2O2CO3/CuBi2O4(50:50) flower-like nanophotocatalyst: Machine and deep-learning algorithms, Process Safety and Environmental Protection, Vol. 184, P. 502-525.
38.   Lv, X-J., Zhou, S., Huang, X., Wang, C., Fu, W-F. 2016. Photocatalytic overall water splitting promoted by SnOx–NiGa2O4 photocatalysts, Applied Catalysis B: Environmental, Vol. 182, P. 220-228.
39.   Lamba, R., Umar, A., Mehta, SK., Kansal, SK.. 2015. ZnO doped SnO2 nanoparticles heterojunction photo-catalyst for environmental remediation, Journal of Alloys and Compounds, Vol. 653, P. 327-33.
40.   Acarbas, O., Suvacı, E., Dogan A. 2007. Preparation of nanosized tin oxide (SnO2) powder by homogeneous precipitation, Ceramics International, Vol. 33, P. 537-542.
41.   Zhang, B., Tian, Y., Zhang, J., Cai, W. 2010. The FTIR studies on the structural and electrical properties of SnO2: F films as a function of hydrofluoric acid concentration, Optoelectronics and Advanced Materials, Rapid Communications, Vol. 4, P.1158-1162.
42.   He, Y., Zhang, L., Fan, M., Wang, X., Walbridge, ML., et al. 2015. Z-scheme SnO2−x/g-C3N4 composite as an efficient photocatalyst for dye degradation and photocatalytic CO2 reduction., Solar Energy Materials and Solar Cells, Vol. 137, P. 175-184.
43.   Cabezuelo, O., Ponce-Gonzalez, LN., Marin, ML., Bosca, F. 2023. A highly efficient supported TiO2 photocatalyst for wastewater remediation in continuous flow, Applied Materials Today, Vol. 35, P. 101947.
44.   Xu, Z., Zhang, C., Zhang, Y., Gu, Y., An, Y. 2022. BiOCl-based photocatalysts: Synthesis methods, structure, property, application, and perspective, Inorganic Chemistry Communications, Vol. 138, P.  109277.
45.   Nadernia, HA., Haghighi, M., Shabani, M. 2022. Textural/structural evolution of cube/cauliflower-like MgSn(OH)6 nanophotocatalyst with excellent photocatalytic degradation of toxic dye pollutants, Ceramics International, Vol.  48, P. 17385-17399.
46.   Najafidoust, A., Haghighi, M., Abbasi, Asl E., Bananifard, H. 2019. Sono-solvothermal design of nanostructured flowerlike BiOI photocatalyst over silica-aerogel with enhanced solar-light-driven property for degradation of organic dyes, Separation and Purification Technology, Vol. 221, P. 101-113.
47.   Shabani, M., Haghighi, M., Kahforoushan, D., Heidari, S. 2019. Grain-like bismuth-rich bismuth/bismuth oxychlorides intra-heterojunction: Efficacious solar-light-driven photodegradation of fluoroquinolone antibiotics and 2-level factorial approach, Journal of the Taiwan Institute of Chemical Engineers, Vol. 96, P. 243-255.
مطالعات علوم محیط زیست
دوره 10، شماره 2
تابستان 1404
صفحه 10225-10244