@Research Paper
<#LINE#>Anion effect on selectivity in 18-crown-6 ether interaction with alkali metal cations<#LINE#>Kalpesh H. @Patil,Gokul P. @Borse,Narendra @Sonawane,Rahul @Garud <#LINE#>1-4<#LINE#>1.ISCA-RJRS-2025-015.pdf<#LINE#>Department of Chemistry, Ranilaxmibai Mahavidyalay, Parola Dist- Jalgaon, India@Department of Chemistry, Ranilaxmibai Mahavidyalay, Parola Dist- Jalgaon, India@Department of Chemistry, BSSMP’S, Arts, Commerce and Science College, Songir, India@Department of Chemistry, Ranilaxmibai Mahavidyalay, Parola Dist- Jalgaon, India<#LINE#>2/8/2025<#LINE#>5/9/2025<#LINE#>The Selectivity complexation of alkali metal cations by 18-crown-6 ether was investigated with particular focus on the effect of various cations at 298.15K using viscosity and density study elucidates how different anions influences the interaction ability and selectivity of alkali metal ions. The presence and nature of anions were found to modulate the host-guest interaction energies, impacting the structural confirmation of common ether complex as well as salvation and electrostatic effects. The excess parameters such as excess molar volume (VE), viscosity deviation (∆η), apparent molar volume (ϕv) were calculated from the experimental data of viscosity and density at 298.15K. These excess calculated data reveals that anions identify significantly changes the thermodynamic parameters and binding selectivity these finding contributes to a deeper understanding of ion recognition mechanism in 18-crown-6 ether system and suggest strategic manipulation of anions for enhanced the selectivity in applications such as ion extraction sensing and catalyst at 298.15K.<#LINE#>Pedersen, C. J. (1988).@The discovery of crown ethers.@Science, 241(4865), 536-540.@Yes$Izatt, R. M., Bradshaw, J. S., Nielsen, S. A., Lamb, J. D., Christensen, J. J., & Sen, D. (1985).@Thermodynamic and kinetic data for cation-macrocycle interaction.@Chemical Reviews, 85(4), 271-339.@Yes$Ohtsu, K., & Ozutsumi, K. (2003).@Thermodynamics of solvation of 18-crown-6 and its alkali-metal complexes in various solvents.@Journal of inclusion phenomena and macrocyclic chemistry, 45(3), 217-224.@Yes$Czech, B. P., Babb, D. A., Son, B., & Bartsch, R. A. (1984).@Functionalized 13-crown-4, 14-crown-4, 15-crown-4, and 16-crown-4 compounds: synthesis and lithium ion complexation.@The Journal of Organic Chemistry, 49(25), 4805-4810.@Yes$Olsher, U., Hankins, M. G., Kim, Y. D., & Bartsch, R. A. (1993).@Anion effect on selectivity in crown ether extraction of alkali metal cations.@Journal of the American Chemical Society, 115(8), 3370-3371.@Yes$Akutagawa, T., Hasegawa, T., Nakamura, T., Takeda, S., Inabe, T., Sugiura, K. I., ... & Underhill, A. E. (2000).@M+ (12-crown-4) supramolecular cations (M+= Na+, K+, Rb+, and NH4+) within Ni (2-thioxo-1, 3-dithiole-4, 5-dithiolate) 2 molecular conductor.@Inorganic Chemistry, 39(12), 2645-2651.@Yes$Amini, M. K., & Shamsipur, M. (1992).@Complex formation of hydronium ion with several crown ethers in 1, 2-dichloroethane, acetonitrile, and nitrobenzene solutions.@Journal of solution chemistry, 21(3), 275-288.@Yes$Semnani, A., & Shamsipur, M. (1991).@A competitive polarographic study of alkaline earth complexes with some crown ethers using the Tl (I)/Tl (Hg) couple as an electrochemical probe.@Journal of electroanalytical chemistry and interfacial electrochemistry, 315(1-2), 95-101.@Yes$El-Nemma, E. M., & Salman, S. R. (2004).@Molecular complexes of crown ethers: Part 8. Effect of surfactant on the charge transfer complexes of 18C6 with picric acid in the presence of alkali metal ions.@Journal of inclusion phenomena and macrocyclic chemistry, 49(3), 267-273.@Yes$Shannon, R. D. (1976).@Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides.@Foundations of Crystallography, 32(5), 751-767.@Yes$Reddy, V. K., Rambabu, K., Devarajulu, T., & Krishnaiah, A. (1995).@Volume of mixing, speed of sound, and viscosity of methyl cellosolve with aliphatic alcohols at 308.15 K.@Journal of Chemical and Engineering Data, 40(1), 124-127.@Yes$Hawrylak, B., Burke, S. E., & Palepu, R. (2000).@Partial molar and excess volumes and adiabatic compressibilities of binary mixtures of ethanolamines with water.@Journal of solution chemistry, 29(6), 575-594.@Yes$Foster, R. (1980).@Electron donor-acceptor complexes.@The Journal of Physical Chemistry, 84(17), 2135-2141.@Yes$Franjo, C., Jimenez, E., Iglesias, T. P., Legido, J. L., & Paz Andrade, M. I. (1995).@Viscosities and Densities of Hexane+ Butan-1-ol,+ Hexan-1-ol, and+ Octan-1-ol at 298.15 K.@Journal of Chemical and Engineering Data, 40(1), 68-70.@Yes$Borse, G. P. (2017).@Viscosities and densities for binary mi.@Research Journal of Chemical, 7(1), 1-7.@Yes$Ali, A., Nain, A. K., & Hyder, S. (1998).@Ion-solvent interaction of sodium iodide and lithium nitrate in N, N-dimethylformamide + ethanol mixtures at various temperatures.@Journal-Indian Chemical Society, 75, 501-505.@Yes$Kapadi, U. R., Hundiwale, D. G. & Patil, N. B. (2003).@Thermodynamic interaction of 2, 3-butanediol with water.@Fluid phase equilibria,  208(1-2), 91-98.@Yes$Kannappan, A. N., Vanaja, S., Palanivelu, N., & Rajendran, V. (1994).@Thermodynamic studies on binary liquid mixtures from ultrasonic data.@Indian Journal of Chemical Technology, 1, 124-124.@Yes
<#LINE#>Studies on Structural and Magnetic Properties of PET/Fe nanocomposite film<#LINE#>Tahir @Yaqoob,G.S. @Mukherjee,Y. @Choyal,M. @Banerjee <#LINE#>5-8<#LINE#>2.ISCA-RJRS-2025-016.pdf<#LINE#>Nanoscience and Nanotechnology Laboratory, School of Physics, Devi Ahilya University, Indore, MP, India@Defence Research & Development Organization (DRDO), DMSRDE, Kanpur, 208013, India@Nanoscience and Nanotechnology Laboratory, School of Physics, Devi Ahilya University, Indore, MP, India@Nanoscience and Nanotechnology Laboratory, School of Physics, Devi Ahilya University, Indore, MP, India<#LINE#>16/8/2025<#LINE#>14/9/2025<#LINE#>Polymer–metal nanocomposites offer a versatile platform for integrating structural flexibility with functional magnetic properties. In this paper, the synthesis and characterization of polyethylene terephthalate/iron (PET/Fe) nanocomposite films prepared via ion beam sputtering technique is reported. Structural investigations using GIXRD confirmed the successful incorporation of body-centred cubic (bcc) Fe nanoparticles into the PET matrix, with 4.65 nm average particle size. The absence of oxide-related peaks demonstrated that the embedded Fe retained its metallic state, while modifications in PET diffraction peaks indicated polymer–Fe nanoparticle interactions. Magneto-optical Kerr effect (MOKE) measurements revealed well-defined ferromagnetic hysteresis loops at all azimuthal orientations, with a coercivity of ~19 Oe. An angular dependence of the saturation field suggested slight stress-induced magnetic anisotropy within the film. The findings of the study are discussed in this paper.<#LINE#>Chiriac, H., Pletea, M., & Hristoforou, E. (2000). Fe-based amorphous thin film as a magnetoelastic sensor material.@Sensors and actuators A: Physical, 81(1-3), 166-169.@undefined@Yes$Nikitin, P. I., Valeiko, M. V., Toporov, A. Y., Ghorbanzadeh, A. M., & Beloglazov, A. A. (1998).@Deposition of thin ferromagnetic films for application in magnetic sensor microsystems.@Sensors and Actuators A: Physical, 68(1-3), 442-446.@Yes$Tong, H. C., Liu, F., Stoev, K., Chen, Y., Shi, X., & Qian, C. (2002).@The dual spin valve head for high density recording.@Journal of magnetism and magnetic materials, 239(1-3), 106-111.@Yes$Kryder, M. H. (1992).@Magnetic thin films for data storage.@Thin solid films, 216(1), 174-180.@Yes$Rakesh, B., Bhagat, N., & Pandey, B. (2022).@Magnetic thin films used for memory devices: a scientometric analysis.@Journal of Scientometric Research, 11(2), 235-245.@Yes$Gan, F. (2008).@Structure and properties of amorphous thin film for optical data storage.@Journal of non-crystalline solids, 354(12-13), 1089-1099.@Yes$Das, B. K., & Rastogi, A. C. (1997).@Thin films for secondary data storage.@IETE Journal of Research, 43(2-3), 221-232.@Yes$Wang, X., Wang, C., Anderson, S., & Zhang, X. (2013).@Characterization of reactively sputtered iron oxide thin films for developing magnetic resonance imaging contrast agents.@In 2013 Transducers & Eurosensors XXVII: The 17th International Conference on Solid-State Sensors, Actuators and Microsystems (Transducers & Eurosensors XXVII), 2403-2406. IEEE.@Yes$Fatima, H., & Kim, K. S. (2018).@Iron-based magnetic nanoparticles for magnetic resonance imaging.@Advanced Powder Technology, 29(11), 2678-2685.@Yes$Bui, A., Guillen, S. G., Sua, A., Nguyen, T. C., Ruiz, A., Carachure, L., & Tian, F. (2022).@Iron-containing metal-organic framework thin film as a drug delivery system.@Colloids and Surfaces A: Physicochemical and Engineering Aspects, 650, 129611.@Yes$Joshi, A., Mukherjee, G. S., Gupta, M., & Banerjee, M. (2023).@Thickness dependent microstructural and magnetic studies of iron embedded PVA nanocomposite films.@AIP Advances, 13(3).@Yes$Nagar, S., Mukherjee, G. S., & Banerjee, M. (2024).@Studies on the structural and magnetic properties of PMMA/Ni nanocomposite system prepared by embedding Ni nanoparticles in the PMMA films.@Materials Chemistry and Physics, 314, 128913.@Yes$Nagar, S., Mukherjee, G. S., & Banerjee, M. (2023).@Structural and magnetic properties of Ni nanoparticles embedded in vinyl polymer nanocomposite films.@In Spin (Vol. 13, No. 02, p. 2340011). World Scientific Publishing Company.@Yes$Sachdev, P., Banerjee, M., & Mukherjee, G. S. (2014).@Magnetic and microstructural studies on PVA/Co nanocomposite prepared by ion beam sputtering technique.@Def Sci J., 64(3), 290-294.@Yes$Czyżewski, W., Jachimczyk, J., Hoffman, Z., Szymoniuk, M., Litak, J., Maciejewski, M., & Torres, K. (2022).@Low-cost cranioplasty—a systematic review of 3D printing in medicine.@Materials, 15(14), 4731.@Yes$Choudhary, A., Mukherjee, G. S., & Banerjee, M. (2025).@Sputtering of metal Nanoparticles in Polymer film to create multiple Properties in the Nanocomposite System.@Research Journal of Recent Sciences, 14(2), 11-17.@Yes$Stetsiv, Y. A., Yatsyshyn, M. M., Nykypanchuk, D., Korniy, S. A., Saldan, I., Reshetnyak, O. V., & Bednarchuk, T. J. (2021).@Characterization of polyaniline thin films prepared on polyethylene terephthalate substrate.@Polymer Bulletin, 78(11), 6251-6265.@Yes$Patterson, A. L. (1939).@The Scherrer formula for X-ray particle size determination.@Physical review, 56(10), 978.@Yes$Kisić, D. D., Nenadović, M. T., Potočnik, J. M., Novaković, M., Noga, P., Vaňa, D., & Rakočević, Z. L. (2020).@Surface layer morphology of the high fluence Fe implanted polyethylene-Correlation with the magnetic and optical behavior.@Vacuum, 171, 109016.@Yes$Joshi, A., Mukherjee, G. S., Gupta, M., & Banerjee, M. (2023).@Thickness dependent microstructural and magnetic studies of iron embedded PVA nanocomposite films.@AIP Advances, 13(3).@Yes
<#LINE#>Utilization of Curry Neem Bark for the Effective Adsorptive Removal of Azithromycin from Aqueous Environment<#LINE#>Gajanand @Patel,Vijita @Diwan,Santosh Kumar @Sar,Durga Prasad @Patel <#LINE#>9-16<#LINE#>3.ISCA-RJRS-2025-017.pdf<#LINE#>Department of Chemistry Shri Shankaracharya Professional University, Bhilai, Chhattisgarh, India@Department of Chemistry Shri Shankaracharya Professional University, Bhilai, Chhattisgarh, India@Department of Applied Chemistry, Bhilai Institute of Technology, Durg, Chhattisgarh, India@Department of Pharmaceutical Chemistry, Sandipani College of Pharmacy, Pendri, Masturi Bilaspur Chhattisgarh, India<#LINE#>29/8/2025<#LINE#>18/9/2025<#LINE#>Because of the extensive usage of antibiotics, especially azithromycin, they are persistent in aquatic ecosystems, which presents dangers to the environment and public health. This study uses a batch experimental approach to examine the effectiveness of azithromycin removal from wastewater. Numerous factors affecting the adsorption process were methodically investigated, including contact time, initial drug concentration, pH, temperature, and adsorbent dosage.  FTIR and SEM techniques were used to characterize the adsorbent. Curry neem bark's effectiveness as a budget-friendly adsorbent for eliminating azithromycin was assessed. The findings demonstrated that adsorption fit the Langmuir isotherm model well and followed pseudo-second-order kinetics, suggesting monolayer adsorption. The best removal effectiveness (up to 78%) was obtained at pH 5 with an adsorbent dosage of 0.12 g and a contact period of 60 minutes. In order to reduce pharmaceutical contamination in water bodies, this study shows that batch adsorption is a practical and effective technique for extracting azithromycin from wastewater.<#LINE#>Hosseinabadi, P., Rezaei, M. R., Sayadi, M. H., & Barani, H. (2025).@Synthesis and photocatalytic degradation of azithromycin by iron/zinc oxide nanoparticle-reinforced carbon nanofibers.@Scientific Reports, 15(1), 31203.@Yes$Kadmi, Y., Ousaadi, M. I., Lakhdari, D., Bachiri, N., Bouta, I., Bouizzar, S., ... & Berkani, M. (2025).@Optimization of azithromycin degradation: Integrating ANN-PSO modeling, intermediates analysis, identification, and microbiological assessment.@Journal of the Taiwan Institute of Chemical Engineers, 166, 105086.@Yes$Castro-Jiménez, C. C., Saldarriaga-Molina, J. C., García, E. F., Torres-Palma, R. A., & Acelas, N. (2025).@Azithromycin removal from water via adsorption on drinking water sludge-derived materials: Kinetics and isotherms studies.@PloS one, 20(1), e0316487.@Yes$Wei, J., Walker, A. S., & Eyre, D. W. (2025).@Addition of macrolide antibiotics for hospital treatment of community-acquired pneumonia.@The Journal of Infectious Diseases,  231(4), e713-e722..@Yes$Parnham, M. J., Haber, V. E., Giamarellos-Bourboulis, E. J., Perletti, G., Verleden, G. M., & Vos, R. (2014).@Azithromycin: mechanisms of action and their relevance for clinical applications.@Pharmacology & therapeutics,  143(2), 225-245.@Yes$Guardiano, M. G., Carena, L., Pazzi, M., Vione, D., & Nogueira, R. F. P. (2025).@Simultaneous heterogeneous photo-Fenton degradation of azithromycin and clarithromycin in wastewater treatment plant effluent.@Journal of Water Process Engineering, 69, 106870.@Yes$Galir, A., Špoljarić Maronić, D., Stević, F., Žuna Pfeiffer, T., Prašnikar, F., Bek, N., ... & Križevac, P. (2025).@Effects of Azithromycin on the Functioning of the Food Web in Freshwater Plankton.@Journal of xenobiotics,  15(5), 145.@Yes$Barathe, P., Kaur, K., Reddy, S., Shriram, V., & Kumar, V. (2024).@Antibiotic pollution and associated antimicrobial resistance in the environment.@Journal of Hazardous Materials Letters, 5, 100105.@Yes$Khyave, A. E., Mafigholami, R., Davood, A., Mahvi, A., & Salimi, L. (2025).@Photocatalytic degradation of azithromycin and ceftriaxone using synthesized Ag/g-C3N4/Fe3O4 nanocomposites in aqueous solution.@Scientific Reports, 15(1), 18726.@Yes$Balarak, D., Mahvi, A. H., Shahbaksh, S., Wahab, M. A., & Abdala, A. (2021).@Adsorptive removal of azithromycin antibiotic from aqueous solution by azolla filiculoides-based activated porous carbon.@Nanomaterials, 11(12), 3281.@Yes$Singh, N. P., Singh, S., & Kumar, A. (2025).@Recent Advances in Azithromycin Removal through The Biochar.@Journal of Microbiology, Biotechnology & Food Sciences, 14(5).@Yes$Patil, M., Singh, S., Kumari, D., Daverey, A., & Dutta, K. (2024).@Adsorption of azithromycin antibiotic from water onto biochar derived from Terminalia chebula and sugarcane bagasse.@Water Practice & Technology, 19(8), 2973-2990..@Yes$Cela-Dablanca, R., Barreiro, A., Rodríguez-López, L., Arias-Estévez, M., Fernández-Sanjurjo, M., Álvarez-Rodríguez, E., & Núñez-Delgado, A. (2024).@Azithromycin removal using pine bark, oak ash and mussel shell.@Environmental Research, 252, 119048.@Yes$Patel, G., Diwan, V., Sar, S. K., & Mahilang, M. (2025).@Effective elimination of azithromycin antibiotic using nanoparticles prepared from curry neem tree bark.@International Journal of Environmental Analytical Chemistry, 1-21.@Yes$Aslan, S., & Şirazi, M. (2020).@Adsorption of sulfonamide antibiotic onto activated carbon prepared from an agro-industrial by-product as low-cost adsorbent: Equilibrium, thermodynamic, and kinetic studies.@Water, Air, & Soil Pollution, 231(5), 222.@Yes$Kostoglou, M., & Karapantsios, T. D. (2022).@Why is the linearized form of pseudo-second order adsorption kinetic model so successful in fitting batch adsorption experimental data?.@Colloids and Interfaces, 6(4), 55.@Yes$Babas, H., Kaichouh, G., Khachani, M., Karbane, M. E., Chakir, A., Guenbour, A., & Zarrouk, A. (2021).@Equilibrium and kinetic studies for removal of antiviral sofosbuvir from aqueous solution by adsorption on expanded perlite: experimental, modelling and optimization.@Surfaces and Interfaces, 23, 100962.@Yes$Ibrahim, S. M., Mohamed, N. S., & Ahmed, M. M. (2023)@Kinetics, Thermodynamics and Adsorption Studies of Copper Azithromycin Complex for Removal of Toxic New Fuchsin Dye from Wastewater.@Clin Case Rep Int.; 7, 1609.@Yes$Alnajrani, M. N., & Alsager, O. A. (2020).@Removal of antibiotics from water by polymer of intrinsic microporosity: Isotherms, kinetics, thermodynamics, and adsorption mechanism.@Scientific reports, 10(1), 794.@Yes$Bakalis, E., & Zerbetto, F. (2025).@Adsorption Kinetics: Classical, Fractal, or Fractional?.@Langmuir, 41(30), 19834-19844.@Yes$Hamasdiq, A. F., Ismail, H. K., & Omer, R. A. (2025).@Adsorption of azithromycin pharmaceutical by polypyrrole and polypyrrole/zinc ferrite@undefined@Yes$magnetite (PPy/ZnFe2O4@undefined@undefined@Yes$Fe3O4) adsorbents synthesized from deep eutectic solvent: Kinetic, isothermic, and thermodynamic studies.@Arabian Journal of Chemistry, 1-18.@undefined@Yes
@Short Review Paper
<#LINE#>Photocatalytic Degradation of Dyes from Industrial Discharge by Metal Oxide Nanoparticles – A Mini Review<#LINE#>S.S. @Kolekar,S.S. @Pingale,S.P. @Jadhav,V.K. @Kadam <#LINE#>17-22<#LINE#>4.ISCA-RJRS-2025-001.pdf<#LINE#>Department of Chemistry, Hutatma Rajguru Mahavidylaya, Rajgurunagar, MS, India@Department of Chemistry, Hutatma Rajguru Mahavidylaya, Rajgurunagar, MS, India@Department of Chemistry, Hutatma Rajguru Mahavidylaya, Rajgurunagar, MS, India@Department of Chemistry, Shri Shiv Chhatrapati College, Junnar, MS, India<#LINE#>4/1/2025<#LINE#>9/3/2025<#LINE#>The rapid growth of industrialization, urbanization, agriculture activities cause the pollution of water. Pollution of water is harmful to living organisms, soil fertility and aquatic organisms. The discharge from dye and textile industries is highly hazardous to living organisms. The various methods have been developed to remove or reduce the dyes contaminants. The photo catalytic degradation is one of the simple and highly efficient methods to degrade the organic pollutant into harmless species like water and CO2.To enhance the photo catalytic activity the metal oxide nanoparticles being used instead of its bulk material. In this review article we focus on the photocatalytic degradation of various dyes utilizing metal oxide nanoparticles as photocatalysts.<#LINE#>Nur Hanis Hayati Hairo, Chin Fhong Soon, Radin Maya Saphira Radin Mohamed, Marlia Morsin, Nurfarina Zainal, Nafarizal Nayan, Che Zalina Zulkifli, Nor Hazlyna Harun. (2021).@A review of nanotechnological applications to detect and control surface water pollution.@Environmental Technology & Innovation, 24, 102032.@Yes$Malvika Mehta, Mahima Sharma1, Kamni Pathania, Pabitra Kumar Jena and Indu Bhushan (2021).@Degradation of synthetic dyes using nanoparticles: A mini review.@Environmental Science and Pollution Research.@Yes$A. Subaihi, A.M. Naglah. (2022).@Facile synthesis and characterization of Fe2O3 nanoparticles using L-lysine and L-serine for efficient photocatalytic degradation of methylene blue dye.@Arabian Journal of Chemistry, 15,103613.@Yes$Kashif Ali Khan, Afzal Shah, Jan Nisar, Abdul Haleem and Iltaf Shah (2023).@Photocatalytic Degradation of Food and Juices Dyes via Photocatalytic Nanomaterials Synthesized through Green Synthetic Route: A Systematic Review.@Molecules, 28, 4600.@Yes$Abdullah Khaled Al-Buriahi, Adel Ali Al-Gheethi, Ponnusamy Senthil Kumar, Radin Maya Saphira Radin Mohamed, Hanita Yusof, Abdullah Faisal Alshalif and Nasradeen A. Khalifa (2022).@Elimination of rhodamine B from textile wastewater using nanoparticle photocatalysts: A review for sustainable approaches.@Chemosphere, 287, 132162.@Yes$Tahani Saad Algarni, Naaser A. Y. Abduh, Abdullah Al Kahtani and Ahmed Aouissi. (2022).@Photocatalytic degradation of some dyes under solar light irradiation using ZnO nanoparticles synthesized from Rosmarinus officinalis extract.@Green Chemistry Letters and Reviews, 15(2), 460–473.@Yes$Asma Rafiq, Muhammad Ikram, S. Ali, Faiza Niaz, Maaz Khan, Qasim Khan and Muhammad Maqbool (2021).@Photocatalytic degradation of dyes using semiconductor photocatalysts to clean industrial water pollution.@Journal of Industrial and Engineering Chemistry, 97, 111–128.@Yes$Monika Patel, Sunita Mishra, Ruchi Verma, Deep Shikha. (2022).@Synthesis of ZnO and CuO nanoparticles via Sol gel method and its characterization by using various technique.@Discover Materials, 2(1).|@Yes$E. Paulson and M. Jothibas (2021).@Significance of thermal interfacing in hematite (α-Fe2O3) nanoparticles synthesized by sol-gel method and its characteristics properties.@Surfaces and Interfaces, 26, 101432.@Yes$Farid I. El-Dossoki, Tarek M. Atwee, Ahmed M. Hamada and Ashraf A. El-Bindary (2021).@Photocatalytic degradation of Remazol Red B and Rhodamine B dyes using TiO2 nanomaterial: estimation of the effective operating parameters.@Desalination and Water Treatment, 233, 319–330.@Yes$U. G. Akpan and B. H. Hameed (2009).@Parameters affecting the photocatalytic degradation of dyes Using TiO2-based photocatalysts: A review.@Journal of Hazardous Materials, 170, 520–529.@Yes$Hyeonhan Lim, Mohammad Yusuf, Sehwan Song, Sungkyun Park and Kang Hyun Park (2021).@Efficient photocatalytic degradation of dyes using photo-deposited Ag nanoparticles on ZnO structures: simple morphological control of ZnO.@RSC Adv., 11, 8709–8717.@Yes$Anoop Singh, Aamir Ahmed, Asha Sharma, Chandan Sharma, Satya Paul, Ajit Khosla and Vinay Gupta Sandeep Arya (2021).@Promising photocatalytic degradation of methyl orange dye via sol-gel synthesized Ag–CdS@undefined@Yes$Pr-TiO2 Core/Shell nanoparticles.@Physica B: Physics of Condensed Matter, 616, 413121.@undefined@Yes$Md. Shakhawat Hossen Bhuiyan, Muhammed Yusuf Miah, Shujit Chandra Paul, Tutun Das Aka, Otun Saha, Md. Mizanur Rahaman, Md. Jahidul Islam Sharif, Ommay Habiba and Md. Ashaduzzaman (2020).@Green synthesis of iron oxide nanoparticle using Carica papaya leaf extract: application for photocatalytic degradation of remazol yellow RR dye and antibacterial activity.@Heliyon, 6, e04603.@Yes$Suman, Saurabh Singh, Ankita, Ashok Kumar, Navish Kataria, Sandeep Kumar and Parmod Kumar (2021).@Photocatalytic activity of α-Fe2O3@undefined@Yes$CeO2 and CeO2@undefined@undefined@Yes$α-Fe2O3 core-shell nanoparticles for degradation of Rose Bengal dye.@Journal of Environmental Chemical Engineering, 9, 106266.@undefined@Yes$A. Tony Dhiwahar, S. Maruthamuthu, R. Marnadu, M. Sundararajan, M. Aslam Manthrammel, Mohd Shkir P. Sakthivel and Vasudeva Reddy Minnam Reddy (2021).@Improved photocatalytic degradation of rhodamine B under visible light and magnetic properties using microwave combustion grown Ni doped copper ferrite spinel nanoparticles.@Solid State Sciences, 113, 106542.@Yes$Min Fua, Yalin Li, Siwei wu, Peng Lu, Jing Liu and Fan Donga (2011).@Sol–gel preparation and enhanced photocatalytic performance of Cu-doped ZnO nanoparticles.@Applied Surface Science, 258, 1587– 1591.@Yes$Farideh Sedighi, Ali Sobhani-Nasab, Mohsen Behpour Mehdi Rahimi-Nasrabadi (2019).@Photocatalytic Degradation of Rhodamine B, and Phenol Red Dyes using NiMn2O4 Nanoparticles Prepared by a New Approach.@J Nanostruct, 9(2), 258-267.@Yes$G. Jayakumar, A. Albert Irudayaraj and A. Dhayal Raj. (2016).@Photocatalytic Degradation of Methylene Blue by Nickel Oxide Nanoparticles.@Materials Today: Proceedings, 4, 11690–11695.@Yes$Xia Wan, Meng Yuan, Shao-long Tie, Sheng Lan. (2013).@Effects of catalyst characters on the photocatalytic activity and process of NiO nanoparticles in the degradation of methylene blue.@Applied Surface Science, 277, 40– 46.@Yes$T. Adinaveen, Thenmozhi Karnan, Stanly Arul Samuel Selvakumar (2019).@Photocatalytic and optical properties of NiO added Nephelium lappaceum L. peel extract: An attempt to convert waste to a valuable product.@Heliyon, 5, e017511.@Yes$Bibi Ayesha, Uzma Jabeen, Attia Naeem, Parveen Kasi, Muhammad Najam Khan Malghani, Sajid Ullah Khan, Javeed Akhtar and Muhammad Aamir (2020).@Synthesis of zinc stannate nanoparticles by sol-gel method for photocatalysis of commercial dyes.@Results in Chemistry, 2, 100023.@Yes$M.A. Kareem, I.T. Bello, H.A. Shittu, P. Sivaprakash, O. Adedokun and S. Arumugam (2022).@Synthesis, characterization, and photocatalytic application of silver doped zinc oxide nanoparticles.@Cleaner Materials, 3, 100041.@Yes$Seerangaraj Vasantharaj, Selvam Sathiyavimal, Palanisamy Senthilkumar, V.N. Kalpana, Govindaraju Rajalakshmi , Mishal Alsehli, Ashraf Elfasakhany and Arivalagan Pugazhendhi (2021).@Enhanced photocatalytic degradation of water pollutants using bio-green synthesis of zinc oxide nanoparticles (ZnO NPs).@Journal of Environmental Chemical Engineering, 9, 105772.@Yes$Jin Kyu Park, Esrat Jahan Rupa, Mohammad Huzaifa Arif, Jin Feng Li, Gokulanathan Anandapadmanaban, Jong Pyo Kang, Mia Kim, Jong Chan Ahn , Reshmi Akter, Deok Chun Yang and Se Chan Kang (2021).@Synthesis of zinc oxide nanoparticles from Gynostemma pentaphyllum extracts and assessment of photocatalytic properties through malachite green dye decolorization under UV illumination-A Green Approach.@Optik-International Journal for Light and Electron Optics, 239, 166249.@Yes$Mohadeseh Yarahmadi, Hossein Maleki-Ghaleh, Masoud Emami Mehr, Ziba Dargahi, Fatemeh Rasouli, M. Hossein Siadati (2021).@Synthesis and characterization of Sr-doped ZnO nanoparticles for Photocatalytic applications.@Journal of Alloys and Compounds, 853,157000.@Yes$Abhijit I. Biradar, Prashant D. Sarvalkar, Shivanand B. Teli, C.A. Pawar, P.S. Patil and Neeraj R. Prasad (2021).@Photocatalytic degradation of dyes using one-step synthesized silica Nanoparticles.@Materials Today: Proceedings, 43, 2832–2838.@Yes