irdpt-202605192020260519200947CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagIran Polymer Technology, Research and Developmentirdpt2538-3345128202163FatemehRafiemanzelat128202151510.66224/irdpt.33023.6.3.5http://irdpt.ir/en/Article/33023http://irdpt.ir/en/Article/Download/33023http://irdpt.ir/en/Article/Download/33023http://irdpt.ir/en/Article/Download/33023http://irdpt.ir/en/Article/Download/33023http://irdpt.ir/en/Article/Download/33023http://irdpt.ir/en/Article/Download/33023http://irdpt.ir/en/Article/Download/330231. Chen P., Wu R., Wang J., Liu Y., Ding C., Xu S., One-pot Preparation of Ultrastrong Double Network Hydrogels, Polymer Research, 19, 1-4, 2012.2. Yang J., Shi F. K., Gong C., Xie X. M., Dual Cross-linked Networks Hydrogels with Unique Swelling Behavior and High Mechanical Strength: Based on Silica Nanoparticle and Hydrophobic Association, Colloid and Interface Science, 381, 107-115, 2012.3. Bu Y., Shen H., Yang F., Yang Y., Wang X., Wu D., Construction of Tough, in Situ Forming Double-network Hydrogels with Good Biocompatibility, ACS Applied Materials & Interfaces, 9, 2205-2212, 2017.4. Shi Z., Li Y., Chen X., Han H., Yang G., Double Network Bacterial Cellulose Hydrogel to Build a Biology–Device Interface, Nanoscale, 6, 970-977, 2014.5. Haque M. A., Kurokawa T., Gong J. P., Super Tough Double Network Hydrogels and Their Application as Biomaterials, Polymer, 53, 1805-1822, 2012.6. Gong J. P., Katsuyama Y., Kurokawa T., Osada Y., Double‐network Hydrogels with Extremely High Mechanical Strength, Advanced Materials, 15, 1155-1158, 2003.7. Gong J. P., Why are Double Network Hydrogels so Tough?, Soft Matter, 6, 2583-2590, 2010.8. Chen Q., Chen H., Zhu L., Zheng J., Fundamentals of Double Network Hydrogels, Journal of Materials Chemistry B, 3, 3654-3676, 2015.9. Nakajima T., Sato H., ZhaoY., Kawahara S., Kurokawa T., Sugahara K., Gong J. P., A universal Molecular Stent Method to Toughen any Hydrogels Based on Double Network Concept, Advanced Functional Materials, 22, 4426-4432, 2012.10. Matsuda T., Nakajima T., Fukuda Y., Hong W., Sakai T., Gong J. P., Yielding criteria of double network hydrogels, Macromolecules, 49, 1865-1872, 2016.11. Zhuang Y., Yu F., Chen H., Zheng J., Ma J., Chen J., Alginate/Graphene Double-network Nanocomposite Hydrogel Beads with Low-swelling, Enhanced Mechanical Properties, and Enhanced Adsorption Capacity, Journal of Materials Chemistry A, 4, 10885-10892, 2016.12. Chen Q., Zhu L., Zhao C., Wang Q., Zheng J., A Robust, One-pot Synthesis of Highly Mechanical and Recoverable Double Network Hydrogels Using Thermoreversible Sol-gel Polysaccharide, Advanced Materials, 25, 4171-4176, 2015.13. Bakarich S. E., Beirne S., Wallace G. G., Spinks G. M., Extrusion Printing of Ionic–covalent Entanglement Hydrogels with High Toughness, Materials Chemistry B, 1, 4939-4946, 2013.14. Ota T., Yoshida K., Tase T., Sato K., Tanaka M., Saito A., Furukawa H., Influence of 3D-Printing Conditions on Physical Properties of Hydrogel Objects, Mechanical Engineering Journal, 5, 17-00538. 2018.15. Nakajima T., Takedomi N., Kurokawa T., Furukawa H., Gong J. P., A Facile Method for Synthesizing Free-shaped and Tough Double Network Hydrogels Using Physically Crosslinked Poly (Vinyl Alcohol) as an Internal Mold, Polymer Chemistry, 1, 693-697, 2010.16. Sun J. Y., Zhao X., Illeperuma W. R., Chaudhuri O., Oh K. H., Mooney D. J., Suo Z., Highly Stretchable and Tough Hydrogels, Nature, 489, 133-136, 2012.17. Li J., Suo, Z., Vlassak J. J., Stiff Strong, and Tough Hydrogels with Good Chemical Stability, Journal of Materials Chemistry B, 2, 6708-6713, 2014.18. Haque M. A., Kurokawa T., Kamita G., Gong J. P., Lamellar Bilayers as Reversible Sacrificial Bonds to Toughen Hydrogel: Hysteresis, Self-recovery, Fatigue Resistance, and Crack Blunting, Macromolecules, 44, 8916-8924, 2011.19. Hu J., Hiwatashi K., Kurokawa T., Liang S. M., Wu Z. L., Gong J. P., Microgel-reinforced Hydrogel Films with High Mechanical Strength and Their Visible Mesoscale Fracture Structure, Macromolecules, 44, 7775-7781, 2011.20. Lin S., Cao C., Wang Q., Gonzalez M., Dolbow J. E., Zhao, X., Design of Stiff, Tough and Stretchy Hydrogel Composites Via Nanoscale Hybrid Crosslinking and Macroscale Fiber Reinforcement, Soft matter, 10, 7519-7527, 2014.21. Zhu L., Xiong C. M., Tang X. F., Wang L. J., Peng K., Yang H. Y., A Double Network Hydrogel with High Mechanical Strength and Shape Memory Properties, Chinese Journal of Chemical Physics, 31, 350-358, 2018.22. Chen Y., Qiao S., Yu, J., Wang Y., Zhu J., Hu Z., A Novel Dual Responsive Nanocomposite Double Network Hydrogel with Good Mechanical Property, In IOP Conference Series: Earth and Environmental Science, 186, 012042, 2018.23. Gu Z., Huang K., Luo Y., Zhang L., Kuang T., Chen, Z., Liao G., Double Network Hydrogel for Tssue Engineering. Wiley Interdisciplinary Reviews, Nanomedicine and Nanobiotechnology, 10, e1520, 2018.24. Bae K. H., Wang L. S., Kurisawa M., Injectable Biodegradable Hydrogels: Progress and Challenges, Journal of Materials Chemistry B, 1, 5371-5388, 2013.25. Chen H., Chen Q., Hu,R., Wang H., Newby B. M. Z., Chang Y., Zheng J., Mechanically Strong Hybrid Double Network Hydrogels with Antifouling Properties, Journal of Materials Chemistry B, 3, 5426-5435, 2015.26. Ying Z., Wang Q., Xie J., Li B., Lin X., Hui S., Novel Electrically-conductive Electro-Responsive Hydrogels for Smart Actuators with a Carbon-nanotube-enriched Three-dimensional Conductive Network and a Physical-phase-type Three-dimensional interpenetrating Network, Journal of Materials Chemistry C, 8, 4192-4205, 2020.MiladGhani1282021172710.66224/irdpt.33024.6.3.17http://irdpt.ir/en/Article/33024http://irdpt.ir/en/Article/Download/33024http://irdpt.ir/en/Article/Download/33024http://irdpt.ir/en/Article/Download/33024http://irdpt.ir/en/Article/Download/33024http://irdpt.ir/en/Article/Download/33024http://irdpt.ir/en/Article/Download/33024http://irdpt.ir/en/Article/Download/33024[1] BelBruno J.J., Molecularly imprinted polymers, Chemical Review, 119, 94-119, 2019.[2] Cristian C.V., Leidy T.S., Germán A.V., Shakeel A., Tomy J.G., Molecularly imprinted polymers for food applications: A review, Trends in Food Science & Technology, 111, 642-669, 2021.[3] Zhao Q., Ma C., Liu J., Chen Z., Zhao H., Li B., Synthesis of magnetic covalent organic framework molecularly imprinted polymers at room temperature: A novel imprinted strategy for thermo-sensitive substance, Talanta, 225, 121958, 2021.[4] Ramanavicius S., Jagminas A., Ramanavicius A., advances in molecularly imprinted polymers based affinity sensors (review), Polymers, 13, 974-985, 2021[5] Wulff G., Vesper R., Grobe M., Sarahan, A., An Enzyme-analogue built polymer, on the synthesis of polymers containing chiral cavities and their use for the resolution of racemates. Makromolecular Chemistry, 178, 2799-2816, 1977.[6] Cui Y., He Z., Xu Y., Su Y., Ding L., Li Y., Fabrication of molecularly imprinted polymers with tunable adsorption capability based on solvent-responsive cross-linker, Chemical Engineering Journal, 405, 126608, 2021.[7] Arshady, R., Mosbach, K., Synthesis of substrate-selective polymers by host-guest polymerization. Makromolecular Chemistry, 182, 687-692, 1981.[8] Lamaoui A., Palacios-Santander J.M., Amin A., Cubillana-Aguiler L., Molecularly imprinted polymers based on polydopamine: Assessment of non-specific adsorption, Microchemical Journal, 164, 106043, 2021.[9] Yano K., Nakagiri T., Takeuchi T., Matsui J., Ikebukuro K., Karube I., Stereoselective recognition of dipeptide derivatives in molecularly imprinted polymers which incorporate an L-valine derivative as a novel functional monomer, Analytical Chimica Acta, 357, 91–98, 1997. [10] Umpleby R.J., Bode M., Shimizu K.D., Measurement of the continuous distribution of binding sites in molecularly imprinted polymers, Analyst, 125, 1261–1265, 2000. [11] Sellergren B., Andersson L., Molecular recognition in macroporous polymers prepared by a substrate-analog imprinting strategy, Journal of Organic Chemistry, 55, 3381–3383, 1990. [12] Caro E., Masque´ N., Marce´ R.M., Borrull F., Cormack P.A.G., Sherrington D.C., Non-covalent and semi-covalent molecularly imprinted polymers for selective on-line solid-phase extraction of 4-nitrophenol from water samples, Journal of Chromatography A, 963, 169–178, 2002.[13] Whitcombe M.J., Rodriguez M.E., Villar P., Vulfson E.N., A new method for the introduction of recognition site functionality into polymers prepared by molecular imprinting synthesis and characterization of polymeric receptors for cholesterol. Journal of American Chemical Society, 117, 7105–7111, 1995.[14] Fujii Y., Matsutani K., Kikuchi K., Formation of a specific coordination cavity for a chiral amino-acid by template synthesis of a polymer Schiff base cobalt(III) Complex, Journal of Chemical Society Chemical Communication, 10, 415–417, 1985.[15] Bouvarel T., Delaunay N., Pichon V., Molecularly imprinted polymers in miniaturized extraction and separation devices, Journal of Separation Science, 44, 1727-1751, 2021.[16] Hu T., Chen R., Wang Q., He C., Liu S., Recent advances and applications of molecularly imprintedpolymers in solid-phase extraction for real sample analysis, Journal of Separation Science, 44, 274-309, 2021.[17] Jamalipour Soufi G., Iravani S., Varma R.S., Molecularly imprinted polymers for the detection of viruses: challenges and opportunities, Analyst, 10, 240-265, 2021.[18] Tamayo F.G., Turiel E., Mart´ın-Esteban A., Molecularly imprinted polymers for solid-phase extraction and solid-phase microextraction: Recent developments and future trends, Journal of Chromatography A, 1152, 32-40, 2007.[19] P´erez-Moral N., Mayes A.G., Molecularly imprinted sensors: overview and applications, Biosensor and Bioelectronics, 21, 1798, 2006.[20] Rycke E.D., Leman O., Dubruel P., Hedström M., Völker M., Beloglazova N., Novel multiplex capacitive sensor based on molecularly imprinted polymers: A promising tool for tracing specific amphetamine synthesis markers in sewage water, Biosensors and Bioelectronics, 178, 113006, 2021.[21] Benachio I., Lobato A., Gonçalves L.M., Employing molecularly imprinted polymers in the development of electroanalytical methodologies for antibiotic determination, Journal of molecular recognition, 34, 1-12, 2021.[22] Ye L., Cormack P.A., Mosbach K., Molecularly imprinted monodisperse microspheres for competitive radioassay. Analytical Communication, 36, 35-38, 1999.[23] Moral N., Mayes A.G., Comparative study of imprinted polymer particles prepared by different polymerization methods. Analytical Chimica Acta, 504, 15-21, 2004.[24] Heravizadeh O.R., Synthesis of molecular imprinted polymer as an absorbent for selective extraction of a triazine herbicide from biological samples, 1, 1-11, 2018[25] Martín-Esteban A., Membrane-protected molecularly imprinted polymers: Towards selectivity improvement of liquid-phase microextraction, TrAC Trends in Analytical Chemistry, 138, 116236, 2021.[26] Guo B., Tong Y., Zhang B., Tian M., Double affinity based molecularly imprinted polymers for selective extraction of luteolin: A combination of synergistic metal chelating and boronate affinity, Microchemical Journal, 160, 105670, 2021.[27] Tan L., Zhou L.D., Jiang Z.F., Ma R.R., Selective separation and inexpensive purification of paclitaxel based on molecularly imprinted polymers modified with ternary deep eutectic solvents, Journal of Pharmaceutical and Biomedical Analysis, 192, 113661, 2021. امیرکرمی1282021294010.66224/irdpt.33025.6.3.29http://irdpt.ir/en/Article/33025http://irdpt.ir/en/Article/Download/33025http://irdpt.ir/en/Article/Download/33025http://irdpt.ir/en/Article/Download/33025http://irdpt.ir/en/Article/Download/33025http://irdpt.ir/en/Article/Download/33025http://irdpt.ir/en/Article/Download/33025http://irdpt.ir/en/Article/Download/330251. Shannon M.A., Bohn P.W., Menachem Elimelech, John G. Georgiadis, Benito J. Marinas, and Anne M. Mayes. Science and Technology for Water Purification in the Coming Decades. Nanoscience and Technology: A Collection of Reviews from Nature Journals, 337-346, 2010.2. Subramani A., and Hoek E.MV., Biofilm Formation, Cleaning, Re-formation on Polyamide Composite Membranes. Desalination , 257, 73-79, 2010.3. Malaeb L., and George M.A., Reverse Osmosis Technology for Water Treatment: State of the Art Review. Desalination , 267, 1-8, 2011.4. Ruth H.H., Woo Y.C., Mezemir D.M., Chul K.B., Park Kwang-Duck., and Choi June-Seok., Reverse Osmosis Membrane Fabrication and Modification Technologies and Future Trends: a Review. Advances in Colloid and Interface Science 276, 102100, 2020.5. Dan Li., and Wang H., Recent Developments in Reverse Osmosis Desalination Membranes. Journal of Materials Chemistry , 20, 4551-4566, 2010.6. Selda E-I., Saffarimiandoab F., Guclu S., Koseoglu-Imer D.Y., Tunaboylu B., Menceloglu Y., Koyuncu I., and Unal S., Surface Modification of Reverse Osmosis Desalination Membranes with Zwitterionic Silane Compounds for Enhanced Organic Fouling Resistance. Industrial & Engineering Chemistry Research , 60 5133-5144, 2021.7. Quanfu An., Feng Li., Yanli Ji., and Huanlin C., Influence of Polyvinyl Alcohol on the Surface Morphology, Separation and Anti-fouling Performance of the Composite Polyamide Nanofiltration Membranes. Journal of Membrane Science , 367, 158-165, 2011.8. Dipak R., Kim Y., Matsuura T., and Arafat H.A., Development of Antifouling Thin-film-composite Membranes for Seawater Desalination. Journal of Membrane Science , 367, 110-118, 2011.9. Lauren F.G., Lawler D.F., Freeman B.D., Marrot Benoit, and Moulin Philippe. Reverse Osmosis Desalination: Water Sources, Technology, and Today's Challenges. Water Research, 43, 2317-2348, 2009.10. Van W., Elizabeth M., Alyson C.S., Sharma M.M., Young-Hye L., and Benny D.F., Surface modification of Commercial Polyamide Desalination Membranes Using Poly (Ethylene Glycol) Diglycidyl Ether to Enhance Membrane Fouling Rresistance. Journal of Membrane Science, 367, 273-287, 2011.11. Zhang Y., Ying W., Guoyuan P., Xiangrong W., Yu Li., Hongwei S., and Yiqun L., Preparation of High Performance Polyamide Membrane by Surface Modification Method for Desalination. Journal of Membrane Science, 573, 11-20, 2019.12. Rana D., and Takeshi M., Surface Modifications for Antifouling Membranes. Chemical Reviews, 110, 2448-2471, 2010.13. Kwon B., Sangyoup L., Jaeweon C., Hyowon A., Dongjoo L., and Heung S.S., Biodegradability, DBP Formation, and Membrane Fouling Potential of Natural Organic Matter: Characterization and Controllability. Environmental Science & Technology 39, 732-739, 200514. Alyson S.C., Elizabeth M., Wagner V., Bryan Hao Ju D.M., Freeman B.D., and Mukul M.S., PEG-coated Reverse Osmosis Membranes: Desalination Properties and Fouling Resistance. Journal of Membrane Science 340, 92-108, 2009.15. Peng W., Tan K.L., Kang E.T., and Neoh K.G., Plasma-induced Immobilization of Poly (Ethylene Glycol) onto Poly (Vinylidene Fluoride) Microporous Membrane. Journal of Membrane Science 195, 103-114, 2002.16. Lei Li., Zhang S., Zhang X., and Zheng G., Polyamide thin Film Composite Membranes Prepared from 3, 4′, 5-biphenyl Triacyl Chloride, 3, 3′, 5, 5′-biphenyl Tetraacyl Chloride and M-phenylenediamine. Journal of Membrane Science 289, 258-267, 2007.17. Jennifer S.L., Pinnau I., Ciobanu I., Ishida K.P., Alvin Ng., and Reinhard M., Effects of Polyether–polyamide Block Copolymer Coating on Performance and Fouling of Reverse Osmosis Membranes. Journal of Membrane Science, 280, 762-770, 2006.18. Liu Li-F., San-Chuan Y., Yong Z., and Cong-Jie G., Study on a Novel Polyamide-Urea Reverse Osmosis Composite Membrane (ICIC–MPD): I. Preparation and Characterization of ICIC–MPD Membrane. Journal of Membrane Science 281, 88-94, 2006.19. Kanagaraj P., Ibrahim MA.M., Wei H., and Changkun L., Membrane Fouling Mitigation for Enhanced Water Flux and High Separation of Humic Acid and Copper ion Using Hydrophilic Polyurethane Modified Cellulose Acetate Ultrafiltration Membranes." Reactive and Functional Polymers, 150, 104538, 2020.20. Etemadi H., Yegani R., and Seyfollahi M., The Effect of Amino Functionalized and Polyethylene Glycol Grafted Nanodiamond on Anti-biofouling Properties of Cellulose Acetate Membrane in Membrane Bioreactor Systems. Separation and Purification Technology 177, 350-362, 2017.21. Zhang Y., Ying W., Min G., Guoyuan P., Hongwei S., Xuerong Y., and Yiqun L., Surface Modification on Thin-film Composite Reverse Osmosis Membrane by Cation Complexation for Antifouling. Journal of Polymer Research, 26, 1-12, 2019.22. Wei X., Zhi W., Jing C., Jixiao W., and Shichang W., A Novel Method of Surface Modification on Tthin-film-composite Reverse Osmosis Membrane by Grafting Hydantoin Derivative. Journal of Membrane Science, 346, 152-162, 2010.23. Wilbert M.C., John P., and Andrew Z., Bench-scale Testing of Surfactant-modified Reverse Osmosis/nanofiltration Membranes. Desalination, 115, 15-32, 1998.24. Liao Y., Chun-Heng L., Miao T., Rong W., and Anthony G. Fane,. Progress in Electrospun Polymeric Nanofibrous Membranes for Water Ttreatment: Fabrication, Modification and Applications. Progress in Polymer Science, 77, 69-94, 2018.25. Zhou Y, Sanchuan Y., Congjie G., and Xianshe F., Surface Modification of Thin Film Composite Polyamide Membranes by Electrostatic Self Deposition of Polycations for Improved Fouling Resistance. Separation and Purification Technology, 66, 287-294, 2009.26. Ba C., and James E., Preparation and Characterization of a Neutrally Charged Antifouling Nanofiltration Membrane by Coating a Layer of Sulfonated Poly (Ether Ether Ketone) on a Positively Charged Nanofiltration Membrane. Journal of Membrane Science 362, 192-201, 2010.27. Chen Y., Tingjian H., Chunhui J., Tianhaoyue Z., Zexi S., Qibin X., Mengjin J., and Pengqing L., Preparation of Antifouling Poly (Ether Ether Ketone) Hollow Fiber Membrane by Ultraviolet Grafting of Polyethylene Glycol. Materials Today Communications, 27, 102326, 2021.28. Hachisuka H., and Kenichi I., Composite Reverse Osmosis Membrane Having a Separation Jayer with Polyvinyl Alcohol Coating and Method of Reverse Osmotic Treatment of Water Using the Same. U.S. Patent 6,177,011, Issued January, 23, 2001.29. Yu S., Zhenhua L., Zhihai C., Xuesong L., Meihong L., and Congjie G., Surface Modification of Thin-film Composite Polyamide Reverse Osmosis Membranes by Coating N-isopropylacrylamide-co-acrylic Acid Copolymers for Improved Membrane Properties. Journal of Membrane Science, 371, 293-306, 2011.30. Sagle A.C., Elizabeth M., Van W., Hao Ju., Bryan D.M., Benny D., Freeman., and Mukul M Sharma., PEG-coated Reverse Osmosis Membranes: Desalination Properties and Fouling Resistance. Journal of Membrane Science, 340, 92-108, 2009.31. Belfer S., Purinson Y., and Kedem O., Surface Modification of Commercial Polyamide Reverse Osmosis Membranes by Radical Grafting: An ATR‐FTIR Study. Acta Polymerica, 49, 11, 574-582, 1998.32. Mankol V., Zhan H., Song Z., Hongyu W., Yunlong Q., Zhi W., and Jixiao W., Sulfonated Reverse Osmosis Membrane Fabricated with Comonomer Having Excellent Scaling and Fouling Resistance. Industrial & Engineering Chemistry Research, 60, 3095-3104, 2021.33. Kang G., Haijun Y., Zhongnan L., and Yiming C., Surface Modification of a Commercial thin Film Composite Polyamide Reverse Osmosis Membrane by Carbodiimide-Induced Grafting with Poly (Ethylene Glycol) Derivatives. Desalination, 275, 1-3, 252-259, 2011.34. Zou L., Vidalis I., Steele D., Michelmore A., Low S.P., and Verberk J.Q.J.C., Surface Hydrophilic Modification of RO Membranes by Plasma Polymerization for Low Organic Fouling. Journal of Membrane Science, 369, 420-428, 2011.35. Yang R., Jingjing X., Gozde O.I., Sze Y.W., and Karen K.G., Surface-tethered Zwitterionic Ultrathin Antifouling Coatings on Reverse Osmosis Membranes by Initiated Chemical Vapor Deposition. Chemistry of Materials, 23, 1263-1272, 2011.36. Mahdavi H., and Rahimi A., Zwitterion Functionalized Graphene Oxide/polyamide thin Film Nanocomposite Membrane: Towards Improved Anti-fouling Performance for Reverse Osmosis. Desalination, 433, 94-107, 2018.37. Kulkarni A., Debabrata M., and William N.G., Flux Enhancement by Hydrophilization of thin Film Composite Reverse Osmosis Membranes. Journal of Membrane Science, 114, 39-50, 1996.38. Lin N.H., Myung-man K., Gregory T.L., and Yoram C., Polymer Surface Nano-structuring of Reverse Osmosis Membranes for Fouling Rresistance and Improved Flux Performance. Journal of Materials Chemistry, 20, 4642-4652, 2010.39. Jeong B.H., Eric M.H., Yushan Y., Arun S., Xiaofei H., Gil H., Asim K.G., and Anna J., Interfacial Polymerization of thin Film Nanocomposites: a New Concept for Reverse Osmosis Membranes. Journal of Membrane Science, 294, 1-7, 2007.40. Kang G.d., and Yi-ming C., Development of Antifouling Reverse Osmosis Membranes for Water Treatment: a Review. Water Research, 46, 584-600, 2012.EhsanAlikhani1282021414910.66224/irdpt.33026.6.3.41http://irdpt.ir/en/Article/33026http://irdpt.ir/en/Article/Download/33026http://irdpt.ir/en/Article/Download/33026http://irdpt.ir/en/Article/Download/33026http://irdpt.ir/en/Article/Download/33026http://irdpt.ir/en/Article/Download/33026http://irdpt.ir/en/Article/Download/33026http://irdpt.ir/en/Article/Download/330261. Sidney Hanna Dodiuk., Goodman H., Handbook of Thermoset Plastics, Third Edition, USA, 555-557, 2014.2. Manas Chanda Salil Roy K., Industrial Polymers Specialty Polymers and Their Applications, CRC Press, Fourth Edition, UK, 139, 2008. 3. Editors: J.R., White De S.K., Rubber Technologist’s Handbook, Rapra Technology Limited, UK, 76, 2001.4. Brydson J. A., Plastics Materials, Seventh Edition, UK, 832 – 839, 1999.5. Liu D., Song L., Song H., Chen J., Tian Q., Chen L., & Sun G., Correlation Between Mechanical Properties and Microscopic Structures of an Optimized Silica Fraction in Silicone Rubber. Composites Science and Technology, 165, 373-379, 2018.6. Pradhan B., Roy S., Srivastava S. K., & Saxena A., Synergistic Effect of Carbon Nanotubes and Clay Platelets in Reinforcing Properties of Silicone Rubber Nano Composites. Journal of Applied Polymer Science, 132, 1-11, 2015.7. Zhang C., Wang J., & Song S, Preparation of a Novel Type of Flame Retardant Diatomite and Its Application in Silicone Rubber Composites. Advanced Powder Technology, 30, 1567-1575, 2019.8. Zhang J., Zhang H., Wang H., Chen F., & ZhaoY., Extruded Conductive Silicone Rubber with High Compression Recovery and Good Aging‐Resistance for Electromagnetic Shielding Applications. Polymer Composites, 40, 1078-1086, 2019.9. Li H., Chen W., Xu J., Li J., Gan L., Chu X., & Du H., Enhanced Thermal Conductivity by Combined Fillers in Polymer Composites. Thermochimica Acta, 676, 198-204, 2019.10. Qi J., Wen Q., Zhu J., & He T., Synthesis of a Novel Intumescent Flame Retardant Based on Phosphorus, Nitrogen, and Silicone, and Application in VMQ. Journal of Thermal Analysis and Calorimetry, 137, 1549-1557, 2019.11. Mi H.Y., Jing X., Huang H.X., & Turng L.S., Novel Polydimethylsiloxane (PDMS) Composites Reinforced with Three-Dimensional Continuous Silica Fibers. Materials Letters, 210, 173-176, 2018.12. Maghsoudi K., Momen G., Jafari R., & Farzaneh M., Direct Replication of Micro-Nanostructures in the Fabrication of Superhydrophobic Silicone Rubber Surfaces by Compression Molding. Applied Surface Science, 458, 619-628, 2018.13. Wu T., Lai X., Li H., Chen Y., Wang Y., Liu T., & Zeng X., Synergistic Enhancement of Vinyltriethoxysilane and Layered Mg–Al Double Hydroxide on the Tracking and Erosion Resistance of Silicone Rubber. Polymer Testing, 84, 106373, 1-12, 2020.14. Shit S.C., & Shah P., A Review on Silicone Rubber. National Academy Science Letters, 36, 355-365, 2013.15. Anyszka R., Bieliński D. M., Pędzich Z., Parys G., Rybiński P., Zarzecka-Napierała, & Szumera, M, Effect of Mineral Filler Additives on Flammability, Processing and Use of Silicone-Based Ceramifiable Composites. Polymer Bulletin, 75, 1731-1751, 2018.16. Hu S., Chen F., Li J. G., Shen Q., Huang Z. X., & Zhang L. M, The Ceramifying Process and Mechanical Properties of Silicone Rubber/Ammonium polyphosphate/Aluminium Hydroxide/mica Composites. Polymer Degradation and Stability, 126, 196-203, 2016.17. Anyszka R., Bieliński D. M., Pędzich Z., & Szumera M., Influence of Surface-Modified Montmorillonites on Properties of Silicone Rubber-Based Ceramizable Composites. Journal of Thermal Analysis and Calorimetry, 119, 111-121, 2015.18. Zhou W. Y., Qi S. H., Zhao H. Z., & Liu N. L., Thermally Conductive Silicone Rubber Reinforced with Boron Nitride Particle. Polymer Composites, 28, 23-28, 2007.19. Chiu H.T., Sukachonmakul T., Kuo M.T., Wang Y.H., & Wattanakul, K, Surface Modification of Aluminum Nitride by Polysilazane and Its Polymer-Derived Amorphous Silicon Oxycarbide Ceramic for the Enhancement of Thermal Conductivity in Silicone Rubber Composite. Applied surface science, 292, 928-936, 2014.20. Yang D., Zhang W., Jiang B., & Guo Y., Silicone Rubber Ablative Composites Improved with Zirconium Carbide or Zirconia. Composites Part A: Applied Science and Manufacturing, 44, 70-77, 2013.21. Zhou C., Yu L., Luo W., Chen Y., Zou H., & Liang M., Ablation Properties of Aluminum Silicate Ceramic Fibers and Calcium Carbonate Filled Silicone Rubber Composites. Journal of Applied Polymer Science, 132, 1-8, 2015.22. Diao S., Zhang S., Yang Z., Feng S., Zhang C., Wang Z., & Wang G, Effect of Tetraphenylphenyl‐Modified Fumed Silica on Silicone Rubber Radiation Resistance. Journal of Applied Polymer Science, 120, 2440-2447, 2011.23. Jerschow P., Silicone Elastomers, iSmithers Rapra Publishing, UK, Report 137, 12, 5-20, 2001.24. Datta R.N., Rubber Curing Systems, iSmithers Rapra Publishing, UK, Report 144, 12, 23, 2002. 25. Diao S., Dong F., Meng J., Ma P., Zhao Y., & Feng, S, Preparation and Properties of Heat-Curable Silicone Rubber through Chloropropyl/Amine Crosslinking Reactions. Materials Chemistry and Physics, 153, 161-167, 2015.26. Dong F., Wang X., Li S., Hao J., Tang X., Kuang, Applications of α, ω‐Telechelic Polydimethylsiloxane as Cross‐Linkers for Preparing High‐Temperature Vulcanized Silicone Rubber. Polymers for Advanced Technologies, 30, 932-940, 2019.27. Dong FY., Diao S., Ma DP., Zhang SY., Feng SY., Preparation and Haracterization of 3‐Chloropropyl Polysiloxane‐Based Heat‐Curable Silicone Rubber Using Polyamidoamine Dendrimers as Cross‐Linkers. React Funct Polym, 96, 14‐20, 2015.28. Dong F., Ma D., & Feng S., Aminopropyl-Modified Silica as Cross-Linkers of Polysiloxane Containing γ-Chloropropyl Groups for Preparing Heat-Curable Silicone Rubber. Polymer Testing, 52, 124-132, 2016.29. Dong F., Zhao P., Dou R., & Feng S., Amine-Functionalized POSS as Cross-Linkers of Polysiloxane Containing γ-Chloropropyl Groups for Preparing Heat-Curable Silicone Rubber. Materials Chemistry and Physics, 208, 19-27, 2018.30. Dong F., Lu H., Feng S., & Tang X., Preparation and Characterization of Silicone Rubber through the Reaction Between γ‐Chloropropyl and Amino Groups with Siloxane Polyamidoamine Dendrimers as Cross‐linkers. Polymers for Advanced Technologies, 29, 934-940, 2018.AmirhoseinYazdanbakhsh1282021515910.66224/irdpt.33027.6.3.51http://irdpt.ir/en/Article/33027http://irdpt.ir/en/Article/Download/33027http://irdpt.ir/en/Article/Download/33027http://irdpt.ir/en/Article/Download/33027http://irdpt.ir/en/Article/Download/33027http://irdpt.ir/en/Article/Download/33027http://irdpt.ir/en/Article/Download/33027http://irdpt.ir/en/Article/Download/330271. Silva A.L.P., Prata J.C., Walker T.R., Campos D., Duarte A.C., Soares A.M., Rethinking and Optimizing Plastic Waste Management Under COVID-19 Pandemic: Policy Solutions Based on Redesign and Reduction of Single-use Plastics and Personal Protective Equipment, Science of the Total Environment, 742, 140565, 2020.2. Khoo K.S., Ho L.Y., Lim H.R., Leong H.Y., and Chew K.W., Plastic Waste Associated With the COVID-19 Pandemic: Crisis or Opportunity?, Journal of hazardous Materials, 417, 126108, 2021.3. Sheldon R.A., and Norton M., Green Chemistry and the Plastic Pollution Challenge: Towards a Circular Economy., Green Chemistry, 22(19), 6310-6322, 2020.4. Ren X., Biodegradable Plastics: a Solution or a Challenge?, Journal of Cleaner Production, 11(1), 27-40, 2003.5. Czigány T., and Ronkay F., The Coronavirus and Plastics, eXPRESS Polymer Letters, 14(6), 510-511, 2020.6. Makki F., Lamb A., and Moukaddem R., Plastics and the Coronavirus Pandemic: a Behavioral Science Perspective, Mind and Society, 1-5, 2020.7. Park S. H., Personal Protective Equipment for Healthcare Workers During the COVID-19 Pandemic., Infection & Chemotherapy, 52(2), 165, 2020.8. Gruenwald H., Covid-19 and PVC, 2021.9. Douglas D., and Douglas R., Addressing the Corona Virus Pandemic: Will a Novel Filtered Eye Mask Help?, International Journal of Infectious Diseases, 95, 340-344, 2020.10. Das O., Neisiany R.E., Capezza A.J., Hedenqvist M. S., Försth M., Xu Q., The Need for Fully Bio-based Facemasks to Counter Coronavirus Outbreaks: A Perspective., Science of the Total Environment, 736, 139611, 2020.11. Howard J., Huang A., Li Z., Tufekci Z., Zdimal V., Van der Westhuizen, H. M., An Evidence Review of Face Masks Against COVID-19, Proceedings of the National Academy of Sciences, 118(4), 2021.12. Saunders G.H., Jackson I.R., and Visram A.S., Impacts of Face Coverings on Communication: an Indirect Impact of COVID-19., International Journal of Audiology, 60(7), 495-506, 2021.13. Parashar N., and Hait S., Plastics in the Time of COVID-19 Pandemic: Protector or polluter?, Science of the Total Environment, 144274, 2020.14. Kunkel M.E., Vasques M.T., Perfeito J.A.J., Zambrana N.R.M., Bina T.D.S., Passoni L.H.D.M., Mass-production and Distribution of Medical Face Shields Using Additive Manufacturing and Injection Molding Process for Healthcare System Support During COVID-19 Pandemic in Brazil, 2020.15. Singh P., Pal K., Chakravraty A., and Ikram S., Execution and Viable Applications of Face Shield “a Safeguard” Against Viral Infections of Cross-protection Studies: A Comprehensive Review, Journal of Molecular Structure, 130443, 2021.16. Gupta D., Simalti A.K., Bansal A., Gupta N., Patki V., Sood A.K., Use of Personal Protective Equipment During Covid-19 Pandemic in Resource Limited Settings-the Barest Minimum Needed, Indian Journal of Practical Pediatrics, 22(2), 83, 2021.17. Ozdemir O., Coronavirus Disease 2019 (COVID-19): Diagnosis and Management, Erciyes Medical Journal, 42, 242-248, 2020.18. Jing Q.L., Liu M.J., Zhang Z.B., Fang L.Q., Yuan J., Zhang A.R., Household Secondary Attack Rate of COVID-19 and Associated Determinants in Guangzhou, China: a Retrospective Cohort Study, The Lancet Infectious Diseases, 20, 1141-1150, 2020.19. Gallup N., Pringle A.M., Oberloier S., Tanikella N.G., and Pearce J.M., Parametric Nasopharyngeal Swab for Sampling COVID-19 and Other Respiratory Viruses: Open Source Design, SLA 3-D Printing and UV Curing System, HardwareX, 8, e00135, 2020.20. Li Y., Zhang R., Zhao J., and Molina M.J., Understanding Transmission and Intervention for the COVID-19 Pandemic in the United States, Science of the Total Environment, 748, 141560, 2020.21. Islam M.M., Ullah S.M.A., Mahmud S., and Raju S.T.U., Breathing aid Devices to Support Novel Coronavirus (COVID-19) Infected Patients, SN Computer Science, 1(5), 1-8, 2020.22. Zuniga J.M., and Cortes A., The Role of Additive Manufacturing and Antimicrobial Polymers in the COVID-19 Pandemic, Expert Review of Medical Devices, 17(6), 477-481, 2020.23. Tareq M.S., Rahman T., Hossain M., and Dorrington P., Additive Manufacturing and the COVID-19 Challenges: An in-depth Study, Journal of Manufacturing Systems, 2021.24. Curk T., Dobnikar J., and Frenkel D., Rational Design of Molecularly Imprinted Polymers, Soft Matter, 12, 35-44, 2016.25. Puoci F., “Monoclonal-Type” Plastic Antibodies for COVID-19 Treatment: what Is the Idea?, Journal of Functional Biomaterials, 11, 2020.26. Parisi O.I., Dattilo M., Patitucci F., Malivindi R., Delbue S., Ferrante P., Design and Development of Plastic Antibodies Against SARS-CoV-2 RBD Based on Molecularly Imprinted Polymers that Inhibit in Vitro Virus Infection, Nanoscale, 2021.hamidrezaheidari1282021917010.66224/irdpt.33028.6.3.91http://irdpt.ir/en/Article/33028http://irdpt.ir/en/Article/Download/33028http://irdpt.ir/en/Article/Download/33028http://irdpt.ir/en/Article/Download/33028http://irdpt.ir/en/Article/Download/33028http://irdpt.ir/en/Article/Download/33028http://irdpt.ir/en/Article/Download/33028http://irdpt.ir/en/Article/Download/330281. Dickinson Eric., Food Colloids Research: Historical Perspective and Outlook, Advances in Colloid and Interface Science, 165, 7-13, 2011.2. Dickinson E., and Euston S.R., Monte Carlo Simulation of Colloidal Systems, Advances in Colloid and Interface Science, 42, 89-148, 1992.3. Raikos V., Effect of Heat Treatment on Milk Protein Functionality at Emulsion Interfaces: A review, Food Hydrocolloids, 24, 259-265, 2010.4. Sejersen M.T., Salomonsen T., Ipsen R., Clark R., Rolin C. and Engelsen, S.B., Zeta Potential of Pectin-stabilised Casein Aggregates in Acidified Milk Drinks, International Dairy Journal, 17, 302-307, 2007.5. Krongsin J., Gamonpilas C., Methacanon P., Panya A. and Goh S.M., On the Stabilisation of Calcium-fortified Acidified Soy Milks by Pomelo Pectin, Food Hydrocolloids, 50, 128-136, 2015.6. Hunter R.J. and Nicol S.K., The Dependence of Plastic Flow Behavior of Clay Suspensions on Surface Properties, Journal of Colloid and Interface Science, 28, 250-259, 1968.7. Russel W.B., Formulation and Processing of Colloidal Dispersions, MRS Online Proceedings Library (OPL), London, 1989.8. Otsuki A., Barry S. and Fornasiero D., Rheological Studies of Nickel Oxide and Quartz/hematite Mixture Systems, Advanced Powder Technology, 22, 471-475, 2011.9. Yaghmur A., De Campo L., Aserin A., Garti N. and Glatter O., Structural Characterization of Five-component Food Grade Oil-in-water Nonionic Microemulsions, Physical Chemistry Chemical Physics, 6, 1524-1533, 2004.10. Franks G.V., Innovative Applications of Controlled Particle Interactions, Chemical Engineering Research and Design, 83, 937-946, 2005.11 Diao M., Taran E., Mahler S. and Nguyen A.V., A Concise Review of Nanoscopic Aspects of Bioleaching Bacteria-mineral Interactions, Advances in Colloid and Interface Science, 212, 45-63, 2014.12. Otsuki A., Coupling Colloidal Forces with Yield Stress of Charged Inorganic Particle Suspension: A Review, Electrophoresis, 39, 690-701, 2018.13. Israelachvili J.N., Intermolecular and Surface Forces, Academic Press, London, 2015. 14. Johnson S.B., Franks G.V., Scales P.J., Boger D.V. and Healy T.W., Surface Chemistry-Rheology Relationships in Concentrated Mineral Suspensions, International Journal of Mineral Processing, 58, 267-304, 2000.15. Ong B.C. and Leong Y.K., Yield Stress of Oxide Dispersions-intermolecular Forces of Adsorbed Small Ionic Additives and Particle Surface Roughness, The Canadian Journal of Chemical Engineering, 90, 1484-1493, 2012.16. Leong Y.K. and Ong B.C., Critical Zeta Potential and the Hamaker Constant of Oxides in Water, Powder Technology, 134, 249-254, 2003.17. Flatt R.J. and Bowen P., Yodel: a Yield Stress Model for Suspensions, Journal of the American Ceramic Society, 89, 1244-1256, 2006.18. Dickinson E., Hydrocolloids at Interfaces and the Influence on the Properties of Dispersed Systems, Food Hydrocolloids, 17, 25-39, 2003.19. Kobayashi M., Skarba M., Galletto P., Cakara D. and Borkovec M., Effects of Heat Treatment on the Aggregation and Charging of Stöber-type Silica, Journal of Colloid and Interface Science, 292, 139-147, 2005.20. Tadros T., General Principles of Colloid Stability and the Role of Surface Forces, Colloid Stability, 1, 1-22, 2007.21. Dickinson E., Hydrocolloids at Interfaces and the Influence on the Properties of Dispersed Systems, Food Hydrocolloids, 17, 25-39, 2003.22. Chan S.Y., Choo W.S., Young D.J. and Loh X.J., Pectin as a Rheology Modifier: Origin, Structure, Commercial Production and Rheology, Carbohydrate Polymers, 161, 118-139, 2017.23. Barnes H.A., Thixotropy-A Review, Journal of Non-Newtonian Fluid Mechanics, 70, 1-33, 1997.24. Boger D.V., Rheology and the Resource Industries, Chemical Engineering Science, 64, 4525-4536, 2009.25. Firth B.A., Flow Properties of Coagulated Colloidal Suspensions: II. Experimental Properties of the Flow Curve Parameters, Journal of Colloid and Interface Science, 57, 257-265, 1976.26. Kapur P.C., Scales P.J., Boger D.V. and Healy T.W., Yield Stress of Suspensions Loaded With Size Distributed Particles, AIChE Journal, 43, 1171-1179, 1997.27. Scales P.J., Johnson S.B., Healy T.W. and Kapur P.C., Shear Yield Stress of Partially Flocculated Colloidal Suspensions, AIChE Journal, 44, 538-544, 1998.28. Harbour P.J., Dixon D.R. and Scales P.J., The role of Natural Organic Matter in Suspension Stability: 2. Modelling of Particle–particle Interaction. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 295, 67-74, 2007.29. Dickinson E., Structuring of Colloidal Particles at Interfaces and the Relationship to Food Emulsion and Foam Stability, Journal of Colloid and Interface Science, 449, 38-45, 2015.30. Yan L., Masliyah J.H. and Xu Z., 2013. Understanding Suspension Rheology of Anisotropically-charged Platy Minerals from Direct Interaction Force Measurement Using AFM. Current Opinion in Colloid & Interface Science, 18, pp.149-156, 2013.