irdpt-202605192020260519200944CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagIran Polymer Technology, Research and Developmentirdpt2538-33459222025102Mohammad MahdiAshtari BarzokiEhsanGaini922202551510.66224/irdpt.49856.10.2.5http://irdpt.ir/en/Article/49856http://irdpt.ir/en/Article/Download/49856http://irdpt.ir/en/Article/Download/49856http://irdpt.ir/en/Article/Download/49856http://irdpt.ir/en/Article/Download/49856http://irdpt.ir/en/Article/Download/49856http://irdpt.ir/en/Article/Download/49856http://irdpt.ir/en/Article/Download/49856G. L. Robertson, Food Packaging. CRC Press, 2016. K. Marsh and B. Bugusu, “Food packaging—roles, materials, and environmental issues,” J. Food Sci., vol. 72, no. 3, pp. R39–R55, 2007. S. Jadhav, S. Gyan, and V. Univeristy, “Study of different methods of Pharmaceutical Packaging. Sapana,” vol. XV, no. February, pp. 254–277, 2023. T. Rydzkowski, J. Wróblewska-Krepsztul, V. K. Thakur, and T. Królikowski, “Current trends of intelligent, smart packagings in new medical applications,” Procedia Comput. Sci., vol. 207, pp. 1271–1282, 2022, doi: 10.1016/j.procs.2022.09.183. A. Hasanvand, “A Review of Multilayer Flexible Packaging Structures,” J. Packag. Sci. Technol., vol. 14, no. 2, pp. 45–56, 2023. Y. Teck Kim, B. Min, and K. Won Kim, General Characteristics of Packaging Materials for Food System. Elsevier Ltd, 2013. S. Roy, T. Ghosh, W. Zhang, and J. W. Rhim, “Recent progress in PBAT-based films and food packaging applications: A mini-review,” Food Chem., vol. 437, no. P1, p. 137822, 2024, doi: 10.1016/j.foodchem.2023.137822. G. Bang and S. W. Kim, “Biodegradable poly(lactic acid)-based hybrid coating materials for food packaging films with gas barrier properties,” J. Ind. Eng. Chem., vol. 18, no. 3, pp. 1063–1068, 2012, doi: 10.1016/j.jiec.2011.12.004. M. Ščetar, M. Kurek, and K. Galić, “Trends in Fruit and Vegetable Packaging,” Univ. Zagreb. Fac. food Technol. Biotechnol. Pierottijeva 6, 10000 Zagreb. Croat., vol. 5, no. 3–4, pp. 69–86, 2010. M. Ščetar, Multilayer packaging materials. 2021. K. L. Yam, The Wiley encyclopedia of packaging technology. John Wiley & Sons, 2010. A. ;ب Mieth, C. ; Simoneau, and E. Hoekstra, Guidance for the identification of polymers in multilayer-LBNA27816ENN. 2016. W. J. John R, Multilayer Flexible Packaging. 2010. Mohammad HosseinKaramiOmidMoeini Jazni VahidYazdanianMohammad AliEtminani Isfahane9222025172810.66224/irdpt.50130.10.2.17http://irdpt.ir/en/Article/50130http://irdpt.ir/en/Article/Download/50130http://irdpt.ir/en/Article/Download/50130http://irdpt.ir/en/Article/Download/50130http://irdpt.ir/en/Article/Download/50130http://irdpt.ir/en/Article/Download/50130http://irdpt.ir/en/Article/Download/50130http://irdpt.ir/en/Article/Download/501301. Jesiya S. G., Vijayan P. P., Vahabi H., Maria H. J., C.S. A., Thomas S., Sustainable Hybrid Green Nanofiller Based on Cellulose Nanofiber for Enhancing the Properties of Epoxy Resin, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 694, 134082, 2024.2. O’Leary M., Hartley R., Radhakrishnan A., Mavrogordato M., McMahon T., Kratz J., Interlaminar Properties of Carbon Fibre/Epoxy Laminates Produced through a Semi-Curing Process, Composites Part A: Applied Science and Manufacturing, 187, 108488, 2024.3. Guadagno L., Naddeo C., Raimondo M., Thermal, Mechanical, and Electrical Performance of Structural Epoxy Resins Filled with Carbon Nanofibers, Journal of Thermal Analysis and Calorimetry, 148, 13095–13106, 2023.4. Mikinka E., Whittaker T., Synaszko P., Whittow W., Zhou G., Dragan K., The Influence of Impact-Induced Damage on Electromagnetic Shielding Behaviour of Carbon Fibre Reinforced Polymer Composites, Composites Part A: Applied Science and Manufacturing, 187, 108464, 2024.5. Yan J., Xu M., Hu X., Liu L., Xiao X., Li B., A Multifunctional Epoxy Composites Based on Cellulose Nanofiber/Carbon Nanotube Aerogels: Simultaneously Enhancing Fire-Safety, Thermal Conductive and Photothermal Performance, Composites Part A: Applied Science and Manufacturing, 187, 108514, 2024.6. Xu Y., Liu S., Xu S., Liu G., Li G., Flexible and Flame Retardant Cotton Fiber-Reinforced CS/CNF/EP Composites For a Sensitive Fire Warning, Chemical Engineering Journal, 500, 156960, 2024.7. Saputri D. D., Saraswati T. E., Raharjo W. W., Anggoro P. A., Reinforcement of Epoxy Resin-Polyimide Composites Using Magnetic-Carbon Nanofiber and Titanium Dioxide as Hybrid Filler for Electromagnetic Interference Shielding Material, Malaysian Journal of Analytical Sciences, 28(5), 1012–1031, 2024.8. Bai G., Niu C., Lang L., Liang X., Gu W., Wei Z., Chen K., Bohinc K., Guo X., In-Situ Formation of Dual-Gradient Hydrogels through Microfluidic Mixing and Co-Extrusion for Constructing an Engineered Antibacterial Platform, Composites Part A: Applied Science and Manufacturing,187, 108497, 2024.9. Klinthoopthamrong N., Thanawan S., Schrodj G., Mougin K., Goh K.-L., Amornsakchai T., Synergistic Toughening of Epoxy Composite with Cellulose Nanofiber and Continuous Pineapple Leaf Fiber as Sustainable Reinforcements, Nanomaterials, 13, 1703, 2023.10. Gharieh A., Sharifian A., Dadkhah S., Enhanced Long-Term Corrosion Resistance and Self-Healing of Epoxy Coating with HQ-Zn-PA Nanocomposite, Scientific Reports, 15, 8154, 2025.11.Zhang L., Yang D., Li Z., Zhai Z., Li X., de La Vega J., Wang D.-Y., Ultrafine iron oxide decorated mesoporous carbon nanotubes as highly efficient flame retardant in epoxy nanocomposites via catalytic charring effect, Sustainable Materials and Technologies, 39, e00845, 2024.12.Ali Z., Yaqoob S., D’Amore A., Impact of Dispersion Methods on Mechanical Properties of Carbon Nanotube (CNT)/Iron Oxide (Fe3O4)/Epoxy Composites, Journal of Carbon Research., 10(3), 66, 2024.13.Qi C., Dam-Johansen K., Weinell C.E., Wu H., Effect of iron powder on zinc reactivity and anticorrosion performance of zinc-rich epoxy coatings, Progress in Organic Coatings, 190, 108403, 2024.14.Shariatmadar M., Gholamhosseini P., Abdorrezaee Z., Ghorbanzadeh S., Feizollahi S., Hosseini F.S., Azad Shahraki F., Mahdavian M., Leveraging polyaniline grafted micaceous iron oxide as a dual active-barrier pigment for anti-corrosion polymer coatings, Surface and Coatings Technology, 479, 130501, 2024.15.Zhong F., Yang X., Chen C., Wang M., Wang B., Xia H., Song J., Cobalt-doped iron-based Prussian blue analogue cubes anchored to phosphorus-nitrogen-covered BN surfaces for enhancing the flame retardancy of epoxy coatings, Progress in Organic Coatings, 198, 2025.16.Ji Z., Shu J., Jing H., Su C., Peng X., Li T., Xu C., Xia M., Wang J., Yang J., Lei W., Hao Q., Enhanced corrosion resistance of zinc-rich epoxy anti-corrosion coatings using graphene-Fe2O3 and HEDP, Journal of Industrial and Engineering Chemistry, 2025.17.Khalil M.M., Gouda M.M., Abbas M.I., Impact of nano Fe2O3 on radiation parameters of epoxy reinforced with nano carbon, Scientific Reports, 14, 21940, 2024. 18.Wang B., Zhang C., Huang B., Wang H., Miao X., Deng W., A facile dip-coating approach to prepare robust superhydrophobic fabric modified by γ-Fe2O3/epoxy resin/lauric acid for oil/water separation, lossless water transportation, and flame retardancy, Surfaces and Interfaces, 45, 103896, 2024.19.Qiao Y., Tao X., Li L., Robust α-Fe2O3/Epoxy Resin Superhydrophobic Coatings for Anti-icing Property, J. Wuhan Univ. Journal of Wuhan University of Technology-Materials Science Edition., 39, 621–626, 2024. 20.Wei Z., Guan J., Yan L., Niu G., The role of nano-Fe2O3 crystal structure on the thermal stability, flame retardancy, and smoke suppression of intumescent flame-retarded epoxy resins, Journal of Vinyl and Additive Technology, 31(1), 59-70, 2024.21.Zhou K., Wu Y., Yin L., Luo J., Lu K., Yu B., Shi Y., Zhang S., Jia S., In situ assembly of polyphosphazene on Fe-MMT nanosheets for high-performance flame-retardant epoxy composites, Polymer Degradation and Stability, 235, 111264, 2025.22.Le Huy C.H., Thanh A.T., Study on fabricating epoxy coatings reinforced with iron oxide flakes and nano silica, Journal of Reinforced Plastics and Composites, 42(13-14), 724-740, 2023. 23.Dorado L., Toledo A.R. de la Osa A., Esteban-Arranz J., Sacristan B., Pellegrin J., Steck L., Sanchez-Silva L., Adhesion enhancement and protection of concrete against aggressive environment using graphite-Fe2O3 modified epoxy coating, Construction and Building Materials, 379, 131179, 2023.24.Shi X.-H., Liu Q.-Y., Li X.-L., Yang S.-Y., Wang D.-Y., Simultaneously improving the fire safety and mechanical properties of epoxy resin with iron phosphonated grafted polyethylenimine, Polymer Degradation and Stability, 206, 110173, 2022.25.Liu C., Li P., Xu Y.J., Epoxy/iron alginate composites with improved fire resistance, smoke suppression and mechanical properties, Journal of Materials Science, 57, 2567–2583, 2022. 26.Chen Q., Huo S., Lu Y., Ding M., Feng J., Huang G., Xu H., Sun Z., Wang Z., Song P., Heterostructured Graphene@Silica@Iron Phenylphosphinate for Fire-Retardant, Strong, Thermally Conductive Yet Electrically Insulated Epoxy Nanocomposites, Small, 20(31), 2310724, 2024.27.Shi G., Zang J., Chen R., Wang X., Wang L., Wang M., Cheng Y., Differences in the magnetic properties of Finemet/FeSi soft magnetic composites prepared with epoxy resin/nano-oxide composite coating layers, Materials Today Communications, 40, 110177, 2024.28.Rathi J.S.L., Ruban Y.J.V., Mon S.G., Waste iron swarf reinforced epoxy/unsaturated polyester particulate composite films fabrication, characterization and peculiarities, Journal of the Indian Chemical Society, 102(3), 101619, 2025.29.Zimmermann I., Eilts F., Galler A.-S., Bayer J., Hober S., Berensmeier S., Immobilizing calcium-dependent affinity ligand onto iron oxide nanoparticles for mild magnetic mAb separation, Biotechnology Reports, 45, 2025.30. Chen Y., Sha A., Jiang W., Lu Q., Du P., Hu K., Li C., Eco-friendly bismuth vanadate/iron oxide yellow composite heat-reflective coating for sustainable pavement: Urban heat island mitigation, Construction and Building Materials, 470, 140645, 2025.ahmadrezaakbarianPedramManafi9222025293910.66224/irdpt.50411.10.2.29http://irdpt.ir/en/Article/50411http://irdpt.ir/en/Article/Download/50411http://irdpt.ir/en/Article/Download/50411http://irdpt.ir/en/Article/Download/50411http://irdpt.ir/en/Article/Download/50411http://irdpt.ir/en/Article/Download/50411http://irdpt.ir/en/Article/Download/50411http://irdpt.ir/en/Article/Download/504111. Lakra, R., et al., A mini-review: Graphene based composites for supercapacitor application. Inorganic Chemistry Communications, 2021. 133: p. 108929. 2. Manafi, P., et al., A study on the microstructural development of gel polymer electrolytes and different imidazolium-based ionic liquids for dye-sensitized solar cells. Journal of Power Sources, 2021. 481: p. 228622. 3. Manafi, P., et al., Microstructural development and rheological study of a nanocomposite gel polymer electrolyte based on functionalized graphene for dye-sensitized solar cells. Polymers, 2020. 12(7): p. 1443. 4. Cui, J., et al., General synthesis of hollow mesoporous conducting polymers by dual-colloid interface co-assembly for high-energy-density micro-supercapacitors. Journal of Energy Chemistry, 2021. 62: p. 145-152. 5. AbdelHamid, A.A., A. Elgamouz, and A.-N. Kawde, Enhanced Supercapacitor Performance of Polypyrrole-Coated Graphenized Electrode by Tuning Electrodeposition Technique. Arabian Journal for Science and Engineering, 2024. 49(7): p. 9175-9192. 6. Wang, Z., et al., Polymers for supercapacitors: Boosting the development of the flexible and wearable energy storage. Materials Science and Engineering: R: Reports, 2020. 139: p. 100520. 7. Zhong, M., M. Zhang, and X. Li, Carbon nanomaterials and their composites for supercapacitors. Carbon Energy, 2022. 4(5): p. 950-985. 8. Oladele, I., et al., Polymer-based nanocomposites for supercapacitor applications: a review on principles, production and products. RSC advances, 2025. 15(10): p. 7509-7534. 9. Hao, L. and D. Yu, Progress of conductive polypyrrole nanocomposites. Synthetic Metals, 2022. 290: p. 117138. 10. Rus, Y.B., et al., Influence of the electrolytic medium on the performance and stability of functionalized graphene-polypyrrole nanocomposites as materials for supercapacitors. Synthetic Metals, 2019. 254: p. 22-28. 11. Teng, W., et al., Hierarchical Poly (3, 4-ethylenedioxythiophene): Poly (styrenesulfonate)/Reduced graphene oxide/Polypyrrole hybrid electrode with excellent rate capability and cycling stability for fiber-shaped supercapacitor. Journal of Colloid and Interface Science, 2023. 636: p. 245-254. 12. Moyseowicz, A., D. Minta, and G. Gryglewicz, Conductive polymer/graphene-based composites for next generation energy storage and sensing applications. ChemElectroChem: e202201145. 2023. 13. Tamang, S., et al., A concise review on GO, rGO and metal oxide/rGO composites: Fabrication and their supercapacitor and catalytic applications. Journal of Alloys and Compounds, 2023. 947: p. 169588. 14. Bonastre, J., J. Molina, and F. Cases, Surface modification of jute fabrics by reduced graphene oxide-conducting polymer coatings for their application in low-cost and eco-friendly supercapacitors. Journal of Energy Storage, 2023. 69: p. 107936. 15. Abdillah, O.B., et al., Recent progress on reduced graphene oxide and polypyrrole composites for high performance supercapacitors: A review. Journal of Energy Storage, 2023. 74: p. 109300. 16. Minisy, I.M., et al., Polypyrrole/Tungsten Carbide Nanocomposites for Electrochemical Applications. ACS Applied Polymer Materials, 2024. 6(14): p. 8244-8253. 17. Yadav, R., et al., High‐performance flexible supercapacitor based on morphology tuned polypyrrole/molybdenum disulfide nanocomposites. Energy Storage, 2023. 5(8): p. e477. 18. Czagany, M., et al., Supercapacitors: An efficient way for energy storage application. Materials, 2024. 17(3): p. 702. 19. Hong, R., et al., Fabrication of polypyrrole hollow nanospheres by hard-template method for supercapacitor electrode material. Molecules, 2024. 29(10): p. 2331. 20. Yazar, S., M.B. Arvas, and K. Gürkan, Synthesis of polythiophene with zigzag morphology on pencil graphite electrode and investigation of energy storage properties in supercapacitors. Journal of Materials Science, 2024. 59(24): p. 10936-10952. 21. Tadesse, M.G., A.S. Ahmmed, and J.F. Lübben, Review on conductive polymer composites for supercapacitor applications. Journal of Composites Science, 2024. 8(2): p. 53. 22. Ionescu, D. and M. Kovaci, Prediction of the Specific Energy of Supercapacitors with Polymeric Materials Using Advanced Molecular Dynamics Simulations. Polymers, 2024. 16(23): p. 3404. 23. Zschiebsch, W., et al., Multifunctionality analysis of structural supercapacitors—A review. Materials, 2024. 17(3): p. 739. 24. Tawade, A.K., et al., Enhanced supercapacitor performance through synergistic electrode design: reduced graphene oxide-polythiophene (rGO-PTs) nanocomposite. Chemical Engineering Journal, 2024. 492: p. 151843. 25. Kamali, A.K., et al., Prospective life cycle assessment of two supercapacitor architectures. ACS Sustainable Chemistry & Engineering, 2023. 11(44): p. 15898-15909. 26. Saadati pour, M., M. Delyanee, and M.Z. Pedram, Innovative Synthesis and Advancement Strategies for GCN as Supercapacitor Electrodes: A Comprehensive Review Revealing New Insights. ACS Applied Energy Materials, 2025. 27. Galloni, M.G., et al., Highly porous polyaniline (PANI): a novel green catalytic method for morphology control. Journal of Materials Science, 2025: p. 1-26. 28. Giri, H., et al., Polyaniline derivatives and their applications, in Trends and Developments in Modern Applications of Polyaniline. 2023, IntechOpen. 29. Ayalew, M.Y., et al., Synthesis of polyaniline nanomaterials for an effective supercapacitor applications. Materials Research Express, 2024. 11(12): p. 125303. 30. Qin, X., et al., Polyaniline-modified graphitic carbon nitride as electrode materials for high-performance supercapacitors. Carbon Letters, 2023. 33(3): p. 781-790.Mohammad Hossein AhmadijafarKhademzadeh Yeganeh9222025415510.66224/irdpt.50835.10.2.41http://irdpt.ir/en/Article/50835http://irdpt.ir/en/Article/Download/50835http://irdpt.ir/en/Article/Download/50835http://irdpt.ir/en/Article/Download/50835http://irdpt.ir/en/Article/Download/50835http://irdpt.ir/en/Article/Download/50835http://irdpt.ir/en/Article/Download/50835http://irdpt.ir/en/Article/Download/508351. Mitragotri S., Lahann J., Physical Approaches to Biomaterial Design, Nature materials , 8,15–23, 2009.2. Chen S., Wang Y., Yang L., Chu C., Cao S., Wang Z., Xue J., You Z., Biodegradable elastomers for biomedical applications, Progress in Polymer Science , 147, 101763, 2023.3. Pashuck E., Stevens M., Designing Regenerative Biomaterial Therapies for the Clinic, Science translational medicine , 8, 160-164, 2012.4. Lakshmi S., Cato T., Biodegradable polymers as biomaterials, Progress in Polymer Science , 32, 762-798, 2007.5. Nair L., Laurencin C., Polymers as biomaterials for tissue engineering and controlled drug delivery, Advances in biochemical engineering/biotechnology , 102, 47-90, 2006. 6. Ullah S., Chen X., Fabrication, applications and challenges of natural biomaterials in tissue engineering, Applied Materials Today, 20, 100656, 2020.7. Lutolf M., Hubbell J., Synthetic biomaterials as instructive extracellular microenvironments for morphogenesis in tissue engineering, Nature biotechnology , 23, 47-55, 2005.8. Bat E., Zhang Z., Feijen J., Grijpma D., Poot A., Biodegradable elastomers for biomedical applications and regenerative medicine, Regenerative medicine, 9, 385-398, 2014. 9. Woodard L., Grunlan M., Hydrolytic degradation and erosion of polyester biomaterials, ACS macro letters , 7, 976-982, 2018. 10. Mabilleau G., Sabokbar A., 7 - In vitro biological test methods to evaluate bioresorbability. Academic, UK , 2008. 11. Ali S., Doherty P., Williams D., The mechanisms of oxidative degradation of biomedical polymers by free radicals, Journal of Applied Polymer Science , 51, 1389-1398, 1994. 12. Wang Y., Ameer G., Sheppard B., Langer R., A tough biodegradable elastomer, Nature biotechnology , 20, 602-606, 2020. 13. Liu G., Hinch B., Beavis A., Mechanisms for the transport of α, ω-dicarboxylates through the mitochondrial inner membrane, Journal of Biological Chemistry , 271, 25338-25344, 1996. 14. Piszko P., Kryszak B., Szustakiewicz, K., Influence of cross-linking time on physico-chemical and mechanical properties of bulk poly (glycerol sebacate). Acta of Bioengineering and Biomechanics, 24(4), 85-93, 2022.15. Risley B., Ding X., Chen Y., Miller P., Wang Y., Citrate crosslinked poly(Glycerol sebacate) with tunable elastomeric properties, Macromolecular Bioscience , 21, 2000301 , 2021. 16. Perin G., Felisberti M., Enzymatic synthesis of poly(Glycerol sebacate): kinetics, chain growth, and branching behavior, Macromolecules , 53, 7925-7935 , 2020. 17. Nijst C., Bruggeman J., Karp J., Ferreira L., Zumbuehl A., Bettinger C., Langer R., Synthesis and characterization of photocurable elastomers from poly(glycerol-co-sebacate), Biomacromolecules , 8, 3067-3073, 2007.18. Pereira M., Ouyang B., Sundback C., Lang N., Friehs I., Mureli S., Pomerant-seva I., McFadden J., Mochel M., Mwizerwa O., Nido P., Sarkar D., Masiakos P., Langer R., Ferreira L., Karp J., A highly tunable biocompatible and multifunctional biodegradable elastomer, Advanced Materials , 25, 1209-1215, 2013. 19. Zhu C., Kustra S., Bettinger C., Photocrosslinkable biodegradable elastomers based on cinnamate-functionalized polyesters, Acta Biomaterialia , 9, 7362-7370, 2013. 20. Ding X, Wu Y., Gao J., Wells A., Lee K., Wang Y., Tyramine functionalization of poly(glycerol sebacate) increases the elasticity of the polymer, Journal of Materials Chemistry B , 5, 6097-6109, 2017. 21. Jia Y., Wang W., Zhou X., Nie W., Chen L., He C., Synthesis and characterization of poly(Glycerol sebacate)-based elastomeric. copolyesters for tissue engineering applications, Polymer Chemistry , 7, 2553-2564, 2016. 22. Patel A., Gaharwar A., Iviglia G., Zhang H., Mukundan S., Mihaila S., Demarchi D., Khademhosseini A., Highly elastomeric poly(glycerol sebacate)-co-poly(ethylene glycol) amphiphilic block copolymers, Biomaterials, 34, 3970-3983, 2013. 23. Zhou L., He H., Jiang C., He S., Preparation and characterization of poly(glycerol sebacate)/cellulose nanocrystals elastomeric composites, Journal of Applied Polymer Science , 132, 42196, 2015. 24. Gaharwar A., Patel A., Dolatshahi-Pirouz A., Zhang H., Rangarajan K., Iviglia G., Shin SR., Hussaine M., Khademhosseini A., Elastomeric nanocomposite scaffolds made from poly(glycerol sebacate) chemically crosslinked with carbon nanotubes, Biomaterials Science , 3, 46-58, 2015. 25. Liu Q., Jiang L., Shi R., Zhang L., Synthesis, preparation, in vitro degradation and application of novel degradable bioelastomers: a review, Progress in Polymer Science , 37, 715-765, 2012.26. Yang J., Webb A., Ameer G., Novel citric acid-based biodegradable elastomers for tissue engineering, Advanced Materials , 16, 511-516, 2004. 27. Qiu H., Yang J., Kodali P., Koh J., Ameer G., A citric acid-based hydroxyapatite composite for orthopedic implants, Biomaterials, 27, 5845-5854, 2006. 28. Gyawali D., Tran R., Guleserian K., Tang L., Yang J., Citric-acid-derived photo-cross-linked biodegradable elastomers, Journal of Biomaterials Science Polymer Edition , 21, 1761-1782, 2010. 29. Du Y., Yu M., Chen X., Ma P., Lei B., Development of biodegradable poly(citrate)-polyhedral oligomeric silsesquioxanes hybrid elastomers with high mechanical properties and osteogenic differentiation activity, ACS Applied Materials & Interfaces, 8, 3079-3091, 2016. 30. Du Y., Ge J., Shao Y., Ma P., Chen X., Lei B., Development of silica grafted poly(1,8-octanediol-co-citrates) hybrid elastomers with highly tunable mechanical properties and biocompatibility, Journal of Materials Chemistry B , 3, 2986-3000, 2015. 31. Qulub F., Widiyanti P., Ady J., Synthesis and characterization of composite poly(1.8 Octanediol-co-Citrate) (POC)/nano-hydroxyapatite as candidate biodegradable bone screw, Journal of Biomimetics, Biomaterials and Biomedical Engineering , 27, 36-43, 2016. 32. Levi-Polyachenko N., Rosenbalm T., Kuthirummal N., Shelton J., Hardin W., Teruel M., Development and characterization of elastic nanocomposites for craniofacial contraction osteogenesis, Journal of Biomedical Materials Research Part B, 103, 407-416, 2015.33. Gunatillake P., Adhikari R., Biodegradable polyurethanes: design, synthesis, properties and potential applications. In: Biodegradable polymers: processing, degradation and applications, Academic ,USA, 2011. 34. Ma Z., Hong Y., Nelson D., Pichamuthu J., Leeson C., Wagner W., Biodegradable polyurethane ureas with variable polyester or polycarbonate soft segments: effects of crystallinity, molecular weight, and composition on mechanical properties, Biomacromolecules, 12, 3265-3274, 2011.35. Hashizume R., Fujimoto K., Hong Y., Guan J., Toma C., Tobita K., Wagner W., Biodegradable elastic patch plasty ameliorates left ventricular ad-verse remodeling after ischemia–reperfusion injury: a preclinical study of a porous polyurethane material in a porcine model, Cardiothoracic surgery, 146, 391, 2013. 36. Ravichandran R., Venugopal J., Sundarrajan S., Mukherjee S., Sridhar R., Ramakrishna S., Expression of cardiac proteins in neonatal cardiomyocytes on PGS/fibrinogen core/shell substrate for Cardiac tissue engineering, International Journal of Cardiology , 167, 1461-1468, 2013. 37. Eilenberg M., Enayati M., Ehebruster D., Grasl C., Walter I., Messner B., Baudis S., Potzmann P., Kaun C., Podesser B., Wojta J., Bergmeister H., Long term evaluation of nanofibrous, bioabsorbable polycarbonate urethane grafts for small diameter vessel replacement in rodents, European Journal of Vascular and Endovascular Surgery , 59, 643-652, 2020. 38. Yan Y., Sencadas V., Jin T., Huang X., Chen J., Wei D., Jiang Z., Tailoring the wettability and mechanical properties of electrospun poly(l-lactic acid)-poly(glycerol sebacate) core-shell membranes for biomedical applications, Journal of Colloid and Interface Science , 508, 87-94, 2017. 39. Wang S., Jeffries E., Gao J., Sun L., You Z., Wang Y., Polyester with pendent acetyl-choline-mimicking functionalities promotes neurite growth, ACS Applied Materials & Interfaces , 8, 9590-9599, 2016. 40. Kerativitayanan P., Tatullo M., Khariton M., Joshi P., Perniconi B., Gaharwar A., Nanoengineered osteoinductive and elastomeric scaffolds for bone tissue engineering, ACS Biomaterials Science & Engineering , 3, 590-600, 2017. 41. Du Y., Yu M., Ge J., Ma P., Chen X., Lei B., Development of a multifunctional platform based on strong, intrinsically photoluminescent and antimicrobial silica-poly(citrates)-based hybrid biodegradable elastomers for bone regeneration, Advanced Functional Materials , 25, 5016-5029, 2015. 42. Tran R., Wang L., Zhang C., Huang M., Tang W., Zhang C., Zhang Z., Jin D., Banik B., Brown J., Xie Z., Bai X., Yang J., Synthesis and characterization of biomimetic citrate-based biodegradable composites, Journal of Biomedical Materials Research Part A , 102, 2521-2532, 2014. 43. Balcioglu S., Parlakpinar H., Vardi N., Denkbas E., Karaaslan M., Gulgen S., Taslidere E., Koytepe S., Ates B., Design of xylose-based semisynthetic polyurethane tissue adhesives with enhanced bioactivity properties, ACS Applied Materials & Interfaces , 8, 4456-4466, 2016. 44. Li Q., Song W, Li J., Ma C., Zhao X., Jiao J., Mrowczynski O., Webb B., Rizk E., Lu D., Liu C., Bioinspired super-strong aqueous synthetic tissue adhesives, Matter , 5, 933-956, 2022. 45. Mahdavi A., Ferreira L., Sundback C., Nichol J., Chan E., Carter D., Bet-tinger C., Patanavanich S., Chignozha L., Ben-Joseph E., Galakatos A., Pryor H., Pomerantseva I., Masiakos P., Faquin W., Zumbuehl A., Hong S., Borenstein J., Vacanti J., Langer R., Karp J., A biodegradable and biocompatible gecko-in-spired tissue adhesive, Proceedings of the National Academy of Sciences of the United States of America , 105, 2307-2312, 2008. SaharAbdollahi BaghbanNargesRabbanikhah9222025577810.66224/irdpt.50921.10.2.57http://irdpt.ir/en/Article/50921http://irdpt.ir/en/Article/Download/50921http://irdpt.ir/en/Article/Download/50921http://irdpt.ir/en/Article/Download/50921http://irdpt.ir/en/Article/Download/50921http://irdpt.ir/en/Article/Download/50921http://irdpt.ir/en/Article/Download/50921http://irdpt.ir/en/Article/Download/509211. Z. Zeng, P. Guo, R. Zhang, Z. Zhao, J. Bao, Q. Wang, Z. Xu, Review of aging evaluation methods for silicone rubber composite insulators, Polymers (Basel), 15(2023)1141.2. F. Faiza, A. Khattak, A. U. Rehman, A. Ali, A. Mahmood, K. Imran, Multi-stressed nano and micro-silica/silicone rubber composites with improved dielectric and high-voltage insulation properties, Polymers (Basel), 13(2021)1400.3. M. Z. Saleem, M. Akbar, Review of the performance of high-voltage composite insulators, Polymers (Basel), 14(2022)431.4. Q. Wang, S. Liu, S. Liu, Z. Zuo, Y. Gao, C. Wu, Super-hydrophobic silicone rubber for outdoor electrical insulation, Nano Today, 58(2024)102406.5. M. Gunasekaran, Basic forensic analysis of polymer concrete high voltage insulation in various applications, IEEE Electrical Insulation Conference, (2020)90–93.6. L. E. Schmidt, A. Krivda, C. H. Ho, M. Portaluppi, Polymer concrete outdoor insulation – experience from laboratory and demonstrator testing, Annual Report Conference on Electrical Insulation and Dielectric Phenomena, (2010)1–3.7. X. Tang, T. Wang, F. Yu, X. Zhang, Q. Zhu, L. Pang, Simple, robust and large-scale fabrication of superhydrophobic surfaces based on silica/polymer composites, RSC Advances, 3(2013)25670.8. X. Zhang, Method for recoating RTV anti-pollution flashover coating on insulator coated with RTV anti-pollution flashover coating, (2016).9. D. Qian, J. Zhou, J. Zheng, J. Cao, J. Wan, H. Fan, Synthesis, curing behaviors and properties of a bio-based trifunctional epoxy silicone modified epoxy thermosets, Polymers (Basel), 14(2022)4391.10. H. Ye, L. Zhu, W. Li, H. Liu, H. Chen, Simple spray deposition of a water-based superhydrophobic coating with high stability for flexible applications, Journal of Materials Chemistry A, 5(2017)9882–9890.11. C. Sunanda, M. N. Dinesh, N. Vasudev, Performance evaluation of silicon rubber insulating material with MgO and ZnO nanofillers, IEEE International Conference on High Voltage Engineering and Application, (2016)1–5.12. C.-F. Jeffrey Kuo, N. Ahmad, S.-Y. Lin, G. R. S. Dewangga, M.-Y. Dong, Synthesis and characteristic applications of silicon resins for the modifying agent in heat conduction, Textile Research Journal, 92(2022)871–885.13. V. S. Joseph, T. Calais, T. Stalin, S. Jain, N. K. Thanigaivel, N. D. Sanandiya, Silicone/epoxy hybrid resins with tunable mechanical and interfacial properties for additive manufacture of soft robots, Applied Materials Today, 22(2021)100979.14. X. Wu, X. Li, J. Zhong, X. Xu, B. Xu, B. Ai, Preparation and characterization of UV-curable silicone resin containing perfluorocyclobutyl aryl ether groups, Silicon, 15(2023)5691–5701.15. L. Wu, X. Wang, L. Ning, J. Han, Z. Wan, M. Lu, Improvement of silicone rubber properties by addition of nano-SiO₂ particles, Journal of Applied Biomaterials & Functional Materials, 14(2016)11–14.16. C. Robeyns, L. Picard, F. Ganachaud, Synthesis, characterization and modification of silicone resins: An augmented review, Progress in Organic Coatings, 125(2018)287–315.17. A. Jahromi, E. Cherney, S. Jayaram, Aging characteristics of RTV silicone rubber insulator coatings, IEEE Transactions on Dielectrics and Electrical Insulation, 15(2008)444–452.18. S. A. Seyedmehdi, H. Zhang, J. Zhu, Superhydrophobic RTV silicone rubber insulator coatings, Applied Surface Science, 258(2012)2972–2976.19. G. Momen, M. Farzaneh, Survey of micro/nanofiller use to improve silicone rubber for outdoor insulators, Reviews on Advanced Materials Science, 27(2011)1–13.20. M. Afendi M. Piah, Effect of ATH filler on the electrical tracking and erosion properties of natural rubber-LLDPE blends under wet contaminated conditions, Journal of Industrial Technology, 13(2004)27–40.21. S. R. Sandler, W. Karo, Silicone resins (polyorganosiloxanes or silicones), (Chapter 4), Organ Chem., 29(1977)114–139.22. H. Khan, M. Amin, M. Ali, M. Iqbal, M. Yasin, Effect of micro/nano-SiO₂ on mechanical, thermal, and electrical properties of silicone rubber, epoxy, and EPDM composites for outdoor electrical insulations, Turk J Electr Eng Comput Sci., 25(2017)1426–1435.23. R. Prabu, S. Usa, K. Udayakumar, M. Khan, S. S. M. Majeed, Electrical insulation characteristics of silicone and EPDM polymeric blends, IEEE Trans Dielectr Electr Insul., 14(2007)1207–1214.24. L. Bazli, S. Eskandarinezhad, N. Kakur, V. Ramachandran, A. Bacigalupe, M. Mansilla, et al., Electrical properties of polymer blend composites based on silicone rubber/EPDM/clay for high voltage insulators, J Compos Compd., 2(2021)18–24.25. J. P. Youngblood, T. J. McCarthy, Ultrahydrophobic polymer surfaces prepared by simultaneous ablation of polypropylene and sputtering of poly(tetrafluoroethylene) using radio frequency plasma, Macromolecules, 32(1999)6800–6806.26. F. Wang, G. Wen, F. Fan, T. Zhang, J. Li, Turn hydrophobic to superhydrophobic of composite insulators by surface fluorination, 2016 IEEE Int. Conf. High Volt. Eng. Appl., (2016)1–4.27. S. A. Seyedmehdi, Functional coatings: superhydrophobic and conductive coatings, (2011).28. S. Abdollahi Baghban, M. Khorasani, G. M. M. Sadeghi, Acoustic damping flexible polyurethane foams: effect of isocyanate index and water content on the soundproofing, J Appl Polym Sci., 136(2019).29. S. Abdollahi Baghban, M. Khorasani, G. Mir Mohamad Sadeghi, Soundproofing flexible polyurethane foams: effect of chemical structure of chain extenders on micro-phase separation and acoustic damping, J Cell Plast., 56(2020)167–185.30. S. Abdollahi Baghban, M. Khorasani, G. M. M. Sadeghi, Soundproofing performance of flexible polyurethane foams as a fractal object, J Polym Res., 27(2020)62.31. S. Abdollahi Baghban, M. Khorasani, Polyurethane foam coating degradation: mechanisms and methods of assessment and prevention of degradation, Basparesh, 6(2016)95–106.32. S. Abdollahi Baghban, M. Khorasani, Flexible acoustic polyurethane foam: an overview of physical structure and chemical properties, Basparesh, 8(2017)90–100.33. H. K. Park, S. W. Yoon, W. W. Chung, B. K. Min, Y. R. Do, Fabrication and characterization of large-scale multifunctional transparent ITO nanorod films, J Mater Chem A, 1(2013)5860.34. M. Nodehi, Epoxy, polyester and vinyl ester based polymer concrete: a review, Innov Infrastruct Solut., 7(2022)64.35. L. Harvanek, T. Tomaskova, V. Mentlik, P. Trnka, Modification of epoxy resin used in high-voltage technology, 2015 16th Int Sci Conf Electr Power Eng., IEEE, (2015)346–349.36. R. Kumar, N. Gupta, Tracking and surface degradation of barium titanate filled silicone rubber nanocomposites, 2015 IEEE Conf Electr Insul Dielectr Phenom., IEEE, (2015)495–498.37. H. Khan, M. Amin, A. Ahmad, M. Yasin, Erosion/tracking resistance investigation of micro/nano-SiO₂ filled RTV-SiR composites for outdoor high voltage insulations, 2017 14th Int Bhurban Conf Appl Sci Technol., IEEE, (2017)15–19.38. G. Wang, M. Lu, H. Yang, Y. Zhao, L. Wu, A novel pollution flashover-resistance RTV rubber coating, 2015 IEEE 11th Int Conf Prop Appl Dielectr Mater., IEEE, (2015)328–331.39. L. H. Meyer, E. A. Cherney, S. H. Jayaram, The role of inorganic fillers in silicone rubber for outdoor insulation: alumina tri-hydrate or silica, IEEE Electr Insul Mag., 20(2004)13–21.40. I. Ramirez, E. Cherney, S. Jayaram, M. Gauthier, Nanofilled silicone dielectrics prepared with surfactant for outdoor insulation applications, IEEE Trans Dielectr Electr Insul., 15(2008)228–235.41. E. A. Cherney, R. Gorur, M. Marzinotto, A. El-Hag, L. Meyer, J. M. George, et al., RTV silicone rubber pre-coated ceramic insulators for transmission lines, IEEE Trans Dielectr Electr Insul., 20(2013)237–244.42. Y. Huo, S. Xiu, L.-Y. Meng, B. Quan, Solvothermal synthesis and applications of micro/nano carbons: a review, Chem Eng J., 451(2023)138572.43. X. Liu, Y. Wen, X. Chen, T. Tang, E. Mijowska, Co-etching effect to convert waste polyethylene terephthalate into hierarchical porous carbon toward excellent capacitive energy storage, Sci Total Environ., 723(2020)138055.44. M. T. Khorasani, H. Mirzadeh, P. G. Sammes, Laser induced surface modification of polydimethylsiloxane as a super-hydrophobic material, Radiat Phys Chem., 47(1996)881–888.45. J. Cheng, G.-P. Cao, Y.-S. Yang, Characterization of sol–gel-derived NiOx xerogels as supercapacitors, J Power Sources, 159(2006)734–741.46. W. Ming, L. van Ravenstein, R. van de Grampel, W. van Gennip, M. Krupers, H. Niemantsverdriet, et al., Low surface energy polymeric films from partially fluorinated photocurable solventless liquid oligoesters, Polym Bull., 47(2001)321–328.47. W. Ming, F. Melis, R. van de Grampel, L. van Ravenstein, M. Tian, R. van der Linde, Low surface energy films based on partially fluorinated isocyanates: the effects of curing temperature, Prog Org Coatings, 48(2003)316–321.48. S.-H. Gao, K.-S. Zhou, M.-K. Lei, L.-S. Wen, Surface modification of silicone rubber by CF₄ radio frequency plasma immersion, Plasma Chem Plasma Process., 28(2008)715–728.49. F. Zhang, Y. Zhou, H. Li, Nanocrystalline NiO as an electrode material for electrochemical capacitor, Mater Chem Phys., 83(2004)260–264.50. R. Rahul, N. Prasad, R. R. Ajith, P. Sajeesh, R. S. Mini, R. S. Kumar, A mould-free soft-lithography approach for rapid, low-cost and bulk fabrication of microfluidic chips using photopolymer sheets, Microfluid Nanofluidics, 27(2023)78 51. Z. Tang, W. Liu, Y. Wang, K. M. Saleheen, Z. Liu, S. Peng, et al., A review on in situ monitoring technology for directed energy deposition of metals, Int J Adv Manuf Technol., 108(2020)3437–3463.52. P. Sharma, F. Ponte, M. J. Lima, N. M. Figueiredo, J. Ferreira, S. Carvalho, Plasma etching of polycarbonate surfaces for improved adhesion of Cr coatings, Appl Surf Sci., 637(2023)157903.53. B. Chen, Z. Wu, M. Tian, T. Feng, C. Yuanwei, X. Luo, Effect of surface morphology change of polystyrene microspheres through etching on protein corona and phagocytic uptake, J Biomater Sci Polym Ed., 31(2020)2381–2395.54. C. Gül, S. Albayrak, Elastomeric nanocoatings, Polym Nanoscale Mater Surf Coatings., Elsevier, (2023)75–90.55. L. Wang, A critical review on robust self-cleaning properties of lotus leaf, Soft Matter, 19(2023)1058–1075.56. N. Vourdas, A. Tserepi, E. Gogolides, Nanotextured super-hydrophobic transparent poly(methyl methacrylate) surfaces using high-density plasma processing, Nanotechnology, 18(2007)125304.57. H. J. Ensikat, P. Ditsche-Kuru, C. Neinhuis, W. Barthlott, Superhydrophobicity in perfection: the outstanding properties of the lotus leaf, Beilstein J Nanotechnol., 2(2011)152–161.58. S. Abdollahi Baghban, M. Ebrahimi, M. Khorasani, S. Bagheri-Khoulenjani, Design of different self-stratifying patterns in a VOC-free light-curable coating containing bio-renewable materials: study on formulation and processing conditions, Prog Org Coatings, 161(2021)106519.59. S. Abdollahi Baghban, M. Ebrahimi, M. Khorasani, S. Bagheri-Khoulenjani, Tailoring a variety of self-stratifying patterns in a light-curable coating on the substrates with different surface free energies, Prog Org Coatings, 171(2022)107023.60. S. Abdollahi Baghban, M. Ebrahimi, M. Khorasani, S. Bagheri-Khoulenjani, Self-stratifying behavior of a novel light-curable coating with gradient hydrophobic properties: computational and experimental study, Prog Org Coatings, 159(2021).61. S. Abdollahi Baghban, A theoretical and practical study of the influence of (met)acrylation on the solubility behavior of radiation curing oligomers for environmentally friendly coatings, Adv Mater New Coatings, 12(2024)224–237.62. S. Abdollahi Baghban, M. Ebrahimi, S. Bagheri-Khoulenjani, M. Khorasani, A highly efficient microwave-assisted synthesis of an LED-curable methacrylated gelatin for bio applications, RSC Adv., 11(2021)14996–15009.63. S. Abdollahi Baghban, M. Ebrahimi, M. Khorasani, A facile method to synthesis of a highly acrylated epoxidized soybean oil with low viscosity: combined experimental and computational approach, Polym Test., 115(2022)107727.64. W. Chen, A. Y. Fadeev, M. C. Hsieh, D. Öner, J. Youngblood, T. J. McCarthy, Ultrahydrophobic and ultralyophobic surfaces: some comments and examples, Langmuir, 15(1999)3395–3399.65. Y. Wang, Y. Xia, Electrochemical capacitance characterization of NiO with ordered mesoporous structure synthesized by template SBA-15, Electrochim Acta, 51(2006)3223–3227.66. T. Nakamura, M. Kozako, M. Hikita, R. Inoue, T. Kondo, Experimental investigation on erosion resistance and hydrophobicity of silicone rubber nanocomposite, 2013 IEEE Int Conf Solid Dielectr., IEEE, (2013)230–233.67. H. Gao, Z. Jia, Z. Guan, L. Wang, K. Zhu, Investigation on field-aged RTV-coated insulators used in heavily contaminated areas, IEEE Trans Power Deliv., 22(2007)1117–1124.68. K. Guo, Y. Du, Y. Wu, X. Mi, X. Li, S. Chen, Morphology and FT-IR analysis of anti-pollution flashover coatings with adding nano SiO₂ particles, IOP Conf Ser Mater Sci Eng., 274(2017)012031.69. Y. Tan, B. Du, C. Liang, X. Guo, H. Zheng, P. Liu, et al., Improving anti-humidity property of a SnO₂-based chemiresistive hydrogen sensor by a breathable and hydrophobic fluoropolymer coating, Langmuir, 38(2022)13833–13840.70. Z. Belamri, Hydrophobic coatings on aluminum substrate based on different metal oxides: Co₃O₄, ZnO, and MgO, Prot Met Phys Chem Surfaces, 60(2024)390–3 71. S. Li, R. Xu, G. Song, B. Li, P. Fang, Q. Fu, et al., Bio-inspired (GO + CNTs)-PU hydrophobic coating via replication of lotus leaf and its enhanced mechanical and anti-corrosion properties, Prog Org Coatings, 159(2021)106414.72. V. S. Saji, 2D hexagonal boron nitride (h-BN) nanosheets in protective coatings: a literature review, Heliyon, 9(2023)e19362.73. H. Gu, J. Guo, X. Zhang, Q. He, Y. Huang, H. A. Colorado, et al., Giant magnetoresistive phosphoric acid doped polyaniline–silica nanocomposites, J Phys Chem C, 117(2013)6426–6436.74. P. C. Okonkwo, I. Ben Belgacem, W. Emori, P. C. Uzoma, Nafion degradation mechanisms in proton exchange membrane fuel cell (PEMFC) system: a review, Int J Hydrogen Energy, 46(2021)27956–27973.75. H. M. Shang, Y. Wang, S. J. Limmer, T. P. Chou, K. Takahashi, G. Z. Cao, Optically transparent superhydrophobic silica-based films, Thin Solid Films, 472(2005)37–43.76. D. Ghosh, S. Bhandari, T. K. Chaki, D. Khastgir, Development of a high performance high voltage insulator for power transmission lines from blends of polydimethylsiloxane/ethylene vinyl acetate containing nanosilica, RSC Adv., 5(2015)57608–57618.77. A. Syakur, Hermawan, H. Sutanto, Determination of hydrophobic contact angle of epoxy resin compound silicon rubber and silica, IOP Conf Ser Mater Sci Eng., 190(2017)012025.78. S. H. Mahdi, W. H. Jassim, I. A. Hamad, K. A. Jasima, Epoxy/silicone rubber blends for voltage insulators and capacitors applications, Energy Procedia, 119(2017)501–506.79. R. Chakraborty, B. S. Reddy, Performance of silicone rubber insulators under thermal and electrical stress, IEEE Trans Ind Appl., 53(2017)2446–2454.80. J. Li, Y. Zhao, J. Hu, L. Shu, X. Shi, Anti-icing performance of a superhydrophobic PDMS/modified nano-silica hybrid coating for insulators, J Adhes Sci Technol., 26(2012)665–679. 81. M. T. Nazir, B. T. Phung, M. Hoffman, Performance of silicone rubber composites with SiO₂ micro/nano-filler under AC corona discharge, IEEE Trans Dielectr Electr Insul., 23(2016)2804–2815.82. S. Liu, S. Liu, Q. Wang, Z. Zuo, L. Wei, Z. Chen, et al., Improving surface performance of silicone rubber for composite insulators by multifunctional nano-coating, Chem Eng J., 451(2023)138679.83. J. Li, Y. Wei, Z. Huang, F. Wang, X. Yan, Z. Wu, Electrohydrodynamic behavior of water droplets on a horizontal superhydrophobic surface and its self-cleaning application, Appl Surf Sci., 403(2017)133–140.84. M. Amin, A. Khattak, M. Ali, Accelerated aging investigation of silicone rubber/silica composites for coating of high-voltage insulators, Electr Eng., 100(2018)217–230.85. F. Farhang, M. Ehsani, S. H. Jazayeri, Effects of the filler type and quantity on the flashover voltage and hydrophobicity of RTV silicone rubber coatings, Iran Polym J., 18(2009)149–157.86. S. M. Ghouse, K. Vijayarekha, Influence of nanofillers in mechanical and electrical properties of polymeric insulation, Int J Mech Eng Technol., 8(2017)466–473.87. M. T. Nazir, B. T. Phung, S. Yu, Y. Zhang, S. Li, Tracking, erosion and thermal distribution of micro‐AlN + nano‐SiO₂ co‐filled silicone rubber for high‐voltage outdoor insulation, High Volt., 3(2018)289–294.88. F. Madidi, G. Momen, M. Farzaneh, Development of a stable TiO₂ nanocomposite self-cleaning coating for outdoor applications, Adv Mater Sci Eng., 2016(2016).89. X. Chen, J. Wang, C. Zhang, W. Yang, J. Lin, X. Bian, et al., Performance of silicone rubber composites using boron nitride to replace alumina tri‐hydrate, High Volt., 6(2021)480–486.90. W. Xiaofeng, W. Jincheng, Z. Yi, Study on the structure and properties of RTV/FR-DOMt nanocomposites, J Exp Nanosci., 11(2016)1058–1073.91. M. T. Nazir, A. Khalid, C. Wang, J.-C. Baena, I. Kabir, S. Akram, et al., Synergistic effect of additives on electrical resistivity, fire and smoke suppression of silicone rubber for high voltage insulation, Compos Commun., 29(2022)101045.92. S. Mohammadnabi, K. Rahmani, Effect of fabrication method on the physical properties of carbon-nanotube/silicone-rubber nanocomposite in high-voltage insulators, J Compos Mater., 57(2023)1959–1968. HamidrezaHaydarimarziyehhosseini9222025799110.66224/irdpt.51188.10.2.79http://irdpt.ir/en/Article/51188http://irdpt.ir/en/Article/Download/51188http://irdpt.ir/en/Article/Download/51188http://irdpt.ir/en/Article/Download/51188http://irdpt.ir/en/Article/Download/51188http://irdpt.ir/en/Article/Download/51188http://irdpt.ir/en/Article/Download/51188http://irdpt.ir/en/Article/Download/51188[1] M. Liu, R. Liu, W. Chen, “Graphene wrapped Cu2O nanocubes: non-enzymatic electrochemical sensors for the detection of glucose and hydrogen peroxide with enhanced stability”, Biosensors and Bioelectronics. 45, 206–212, 2013. [2] G. Jiang, Z. Lin, C. Chen, L. Zhu, Q. Chang, N. Wang, W. Wei, H. Tang, “TiO2 nanoparticles assembled on graphene oxide nanosheets with high photocatalytic activity for removal of pollutants”, Carbon. 49, 2693–2701, 2011. [3] M. Morton, Rubber technology, Springer Science & Business Media, 2013. [4] Sun, C., et al., “Enhanced cross-linking performances and carbon black (CB) dispersion in solution styrene butadiene rubber (SSBR) filled with triazine-based graphdiyne (TGDY)”. Composites Science and Technology, 223, p. 109438, 2022. [5] Y. Ikeda, A. Kato, S. Kohjiya, Y. Nakajima, Rubber Science, Springer, 2018. [6] Hosseini, S. M., Razzaghi-Kashani, M., "Catalytic and networking effects of carbon black on the kinetics and conversion of sulfur vulcanization in styrene butadiene rubber", Soft Matter, 14 (45), 9194-9208, 2018. [7] K.S. Lee, A. Whelan, Developments in Rubber Technology—4, Springer Science & Business Media, 2012. [8] J.E. Mark, B. Erman, M. Roland, The science and technology of rubber, Academic press, 2013. [9] Franco-Urquiza, Edgar Adrian. "Clay-based polymer nanocomposites: essential work of fracture", Polymers, 13(15), 2399, 2021. [10] M. Hosokawa, K. Nogi, M. Naito, T. Yokoyama, Nanoparticle technology handbook, Elsevier, 2012. [11] S. Thomas, R. Stephen, Rubber nanocomposites: preparation, properties and applications, John Wiley & Sons, 2010. [12] K.K. Kar, S. Rana, J. Pandey, Handbook of polymer nanocomposites. Processing, performance and application, Volume B: Carbon Nanotube Based Polymer Nanocomposites, Springer Heidelberg New York Dordrecht, London. 2015. [13] de Oliveira, A. Dantas, and C. Augusto Gonçalves Beatrice. "Polymer nanocomposites with different types of nanofiller", Nanocomposites-recent evolutions, 103-104, 2018. [14] M.L. Di Lorenzo, M.E. Errico, M. Avella, “Thermal and morphological characterization of poly (ethylene terephthalate)/calcium carbonate nanocomposites”, Journal of Materials Science. 37, 2351–2358, 2002. [15] Y. Zhan, J. Wu, H. Xia, N. Yan, G. Fei, G. Yuan, “Dispersion and Exfoliation of Graphene in Rubber by an Ultrasonically‐Assisted Latex Mixing and In situ Reduction Process”, Macromolecular Materials and Engineering. 296, 590–602, 2011. [16] M.N. Ismail, A.I. Khalaf, “Styrene–butadiene rubber/graphite powder composites: Rheometrical, physicomechanical, and morphological properties”, Journal of Applied Polymer Science. 120, 298–304, 2011. [17] T. V Varghese, H.A. Kumar, S. Anitha, S. Ratheesh, R.S. Rajeev, V.L. Rao, “Reinforcement of acrylonitrile butadiene rubber using pristine few layer graphene and its hybrid fillers”, Carbon. 61, 476–486, 2013. [18] V.M. Litvinov, P.A.M. Steeman, “EPDM− Carbon black interactions and the reinforcement mechanisms, as studied by low-resolution 1H NMR”, Macromolecules. 32, 8476–8490, 1999. [19] Y. Wu, W. Zhao, L. Zhang, “Improvement of Flex‐Fatigue Life of Carbon‐Black‐Filled Styrene‐Butadiene Rubber by Addition of Nanodispersed Clay”, Macromolecular Materials and Engineering. 291, 944–949, 2006. [20] S.M. Hosseini, M. Razzaghi-Kashani, “Vulcanization kinetics of nano-silica filled styrene butadiene rubber”, Polymer. 55, 6426–6434, 2014. [21] M.A. Semsarzadeh, Z.B.M. Ghasem, G.H.R. Bakhshandeh, “Effect of carbon black on rate constant and activation energy of vulcanization in EPDM/BR and EPDM/NR blends”, (2005). [22] Z.H. Li, J. Zhang, S.J. Chen, “Effects of carbon blacks with various structures on vulcanization and reinforcement of filled ethylene-propylene-diene rubber”, Express Polymer Letters. 2, 695–704, 2008. [23] A. Allahbakhsh, S. Mazinani, M.R. Kalaee, F. Sharif, “Cure kinetics and chemorheology of EPDM/graphene oxide nanocomposites”, Thermochimica Acta. 563, 22–32, 2013. [24] J. Ma, Y. Wang, L. Zhang, Y. Wu, “Improvement of cutting and chipping resistance of carbon black‐filled styrene butadiene rubber by addition of nanodispersed clay”, Journal of Applied Polymer Science. 125, 3484–3489, 2012. [25] S. Chakraborty, S. Kar, S. Dasgupta, R. Mukhopadhyay, S. Bandyopadhyay, M. Joshi, S.C. Ameta, “Effect of treatment of Bis (3‐triethoxysilyl propyl) tetrasulfane on physical property of in situ sodium activated and organomodified bentonite clay–SBR rubber nanocomposite”, Journal of Applied Polymer Science. 116, 1660–1670, 2010. [26] Y. Sun, Y. Luo, D. Jia, “Preparation and properties of natural rubber nanocomposites with solid‐state organomodified montmorillonite”, Journal of Applied Polymer Science. 107, 2786–2792, 2008. [27] M. Karimtehrani, P.E. Namin, I. Ghasemi, “Functionalization of Graphene Nanoplatelet and the Shape Memory Properties of Nanocomposite Based on Thermoplastic Elastomer Polyurethane/Poly (vinyl chloride)/Graphene Nanoplateletes”, Iran. J. Polym. Sci. Technol. 30, 287–297, 2017. [28] S.M.R. Paran, G. Naderi, M.H.R. Ghoreishy, “Microstructure and mechanical properties of thermoplastic elastomer nanocomposites based on PA6/NBR/HNT”, Polymer Composites. 38, 2017. [29] J.A. Gopi, S.K. Patel, A.K. Chandra, D.K. Tripathy, “SBR-clay-carbon black hybrid nanocomposites for tire tread application”, Journal of Polymer Research. 18, 1625–1634, 2011. [30] S. Ahmadi-Shooli, M. Tavakoli, “The Properties of SBR/ENR50 Blend Containing Nanoclay/Carbon Black Dual Filler System Cured by Electron Beam”, Iranian Journal of Polymer Science and Technology. 30, 127–137, 2017. [31] M. Maiti, S. Sadhu, A.K. Bhowmick, “Effect of carbon black on properties of rubber nanocomposites”, Journal of Applied Polymer Science. 96, 443–451, 2005. [32] S.-J. He, Y.-Q. Wang, M.-M. Xi, J. Lin, Y. Xue, L.-Q. Zhang, “Prevention of oxide aging acceleration by nano-dispersed clay in styrene-butadiene rubber matrix”, Polymer Degradation and Stability. 98, 1773–1779, 2013. [33] Y. Liu, L. Li, Q. Wang, X. Zhang, “Fracture properties of natural rubber filled with hybrid carbon black/nanoclay”, Journal of Polymer Research. 18, 859–867, 2011. [34] S. Praveen, P.K. Chattopadhyay, P. Albert, V.G. Dalvi, B.C. Chakraborty, S. Chattopadhyay, “Synergistic effect of carbon black and nanoclay fillers in styrene butadiene rubber matrix: Development of dual structure”, Composites Part A: Applied Science and Manufacturing. 40, 309–316, 2009. [35] R. Singh, M. D. Shah, S. K. Jain, S. C. Shit, R. Giri, “Elastomeric composite: mechanical and thermal properties of styrene butadiene rubber (SBR) based on carbon black and nanoclay”, Journal of information knowledge and research in mechanical engineering. 2, 515-521, 2013. [36] Q. Guo, F. Zaïri, H. Baraket, M. Chaabane, X. Guo, “Pre-stretch dependency of the cyclic dissipation in carbon-filled SBR”, European Polymer Journal. 96, 145–158, 2017. [37] S. Sadhu, A.K. Bhowmick, “Effect of Chain Length of Amine and Nature and Loading of Clay on Styrene-Butadiene Rubber-Clay Nanocomposites”, Rubber Chemistry and Technology. 76, 860–875, 2003.