-

irdpt-140502292014050229200909CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagIran Polymer Technology, Research and Developmentirdpt2538-33451219201723-shokofehakim1219201751610.66224/irdpt.27510.2.3.5http://irdpt.ir/fa/Article/27510http://irdpt.ir/fa/Article/Download/27510http://irdpt.ir/fa/Article/Download/27510http://irdpt.ir/fa/Article/Download/27510http://irdpt.ir/fa/Article/Download/27510http://irdpt.ir/fa/Article/Download/27510http://irdpt.ir/fa/Article/Download/27510http://irdpt.ir/fa/Article/Download/275101. Moore E., Propylene Handbook, Hanser, Germany, 1996. 2. Ismael A., Molecular Weight Effects on Crystallization of Propylene, PhD Thesis, Stellenbosch University, 2011. 3. شکوفه حکیم، مهدی نکومنش، علی شاهرخی نیا، اثر الکترون¬دهنده¬ها بر پلیمر شدن پروپیلن با کاتالیزور زیگلر – ناتا، بسپارش، سال سوم، شماره1، 39-48، 1392. 4. Sacchi M., Forlini M., Tritto I., Zannoni G., Activation Effect of Alkoxysilanes as External Donors in Magnesium Chloride-Supported Ziegler-Natta Catalysts, Macromolecules, 25, 5914-5918, 1992. 5. Terano M., kataoka T., Keii T., Analysis of MgCl2-Supported High-yield Catalysts by Thermal Analysis and Infrared Spectroscopy, Makromolekulare Chemie, 7, 725-731, 1986. 6. Marigo A., Marega C., Saini R., Camurati, I., Influence of Regioirregular Structural Units on the Crystallization of Isotactic Polypropylene, J. Appl. Polym. Sci., 79, 2, 375-384, 2001. 7. Proto A., Oliva L., Pellecchia C., Sivak A.J., Cullo L.A., Isotactic-specific Polymerization of Propene with Supported Catalysts in the Presence of Different Modifiers, Macromolecules, 23, 2904-2907, 1990. 8. Kissin Y.V., Chadwick J.C., Mingozzi I., Morini G., Isoselectivity Distribution of Isospecific Centers in Supported Titanium-based Ziegler-Natta Catalysts, Macromol. Chem. and Phys., 207, 1344-1350, 2006. 9. Kang J., Yang F., Tong W., Polymerization Control and Fast Characterization of The Stereo-defect Distribution of Z-N IPP, Eur. Polym. J., 28, 425-434, 2012. 10. Jamjah R., Polyolefins, Idepardazan Pub., Iran, 3, 83–110, 2010 11. Sacchi M.C., Forlini F., Tritto I., Mendichi R., Zannoni G., Noristi L., Activation Effect of Alkoxysilanes as External Donors in MgCl2-Supported Ziegler-Natta Catalysts, Macromolecules., 25, 5914-5918, 1992. 12. Moore J., Polypropylene Handbook, Hanser/Gradner., Cincinnati, 14, 1996. 13. Harkonen M., Kuutti L., Seppala, J., External Silane Donors in Z-N Catalysis, Computer-based Molecular Model Calculations on Alkoxysilanes, Makromol. Chem., 193, 1413-1421, 1992. 14. Zhang H. X., Lee Y. J., Park J. R., Lee D. H., Yoon K. B., Control of Molecular Weight Distribution of polypropylene obtained by Commercial Ziegler -natta catalyst: Effect of External electron Donor, Macromol. Res., 19, 622-628, 2011. 15. Matsuoka H., Liu B., Nakatani H., Nishiyama I., Terano M., Active Sites Deterioration of MgCl2 Supported Z-N Catalyst Induced by Electron Donor Extraction by Alkylaluminum, Polym. Int., 51, 781-784, 2002. 16. Alshaiban A., Propylene Polymerization using 4th Generation Z-N Catalysts: Polymerization kinetics and Polymer Microstructure Investigation, PhD thesis, Waterloo university, 2011. 17. Sukhdeep K., Virendra R., Synthesis of Polypropylene with Varied Microstructural and Molecular Characteristics Supported Titanium Catalyst System, J. Polym. Res., 18, 235-239, 2011. 18. Soares J.B.P., Kim J.D., Rempel G.L., Analysis and Control of the Molecular Weight and Chemical Composition Distribution of Polyolefins Made with Metallocene and Ziegler- Natta Catalysts, Ind. Eng. Chem. Res., 36, 1144, 1997. 19. Xu J., Feng L., Application of Temperature Rising Elution Fractionation in Polyolefins, Eur. Polym. J., 36, 5, 867-878, 2000. 20. Alshaiban A., Soares J.B.P., Effect of Hydrogen and External Donor on the Microstructure of Polypropylene Made with a 4th Generation Ziegler–Natta Catalyst, Macromol. React. Eng. 7(3-4), 135-145, 2013. 21. Forte M. C. and Coutinho F. M. B., Highly Active Magnesium Chloride Supported Ziegler-Natta Catalysts with Controlled Morphology, Eur. Polym. J., 32, 2, 223–231, 1996. 22. Chadwick J.C., Morini G., Balbontin G., Camurati I., Heere J.J.R., Mingozzi I. and Testoni F., Effects of Internal and External Donors on the Regio- and Stereoselectivity of Active Species in MgCl2-Supported Catalysts for Propene Polymerization, Macromol. Chem. Phys., 202, 1995-2002, 2001. 23. Amer I., Molecular Weight Effects on Crystallization of Polypropylene, PhD Thesis , Department of Chemistry and Polymer Science of Pretoria University, 2011. 24. Hakim S., Nekoomanesh M. and ShahrokhiNia A., The Effect of Mixed and Individual Silane External Donors on the Stereo–Defect Distribution, Active sites and Properties of Polypropylene synthesized with 4th Generation Ziegler-Natta Catalyst, Polym. Sci. A., 57, 5, 573-580, 2015. 25. Harding G. W., van Reenen A. J., Polymerization and Structure-property Relationships of Ziegler-Natta Catalyzed Isotactic Polypropylenes, Eur. Polym. J., 47, 70, 2011. -mitratavakoli12192017172610.66224/irdpt.27511.2.3.17http://irdpt.ir/fa/Article/27511http://irdpt.ir/fa/Article/Download/27511http://irdpt.ir/fa/Article/Download/27511http://irdpt.ir/fa/Article/Download/27511http://irdpt.ir/fa/Article/Download/27511http://irdpt.ir/fa/Article/Download/27511http://irdpt.ir/fa/Article/Download/27511http://irdpt.ir/fa/Article/Download/275111. Yu L, Shearer C, Shapter J. Recent development of carbon nanotube transparent conductive films, Chem. Rev., 116, 13413-13453, 2016. 2. Kumar S., Rani R., Dilbaghi N., Tankeshwar K., Kim KH., Carbon nanotubes: a novel material for multifaceted applications in human healthcare, Chem. Soc. Rev., 46, 158-196, 2017. 3. Gholizadeh S., Moztarzadeh F., Haghighipour N., Ghazizadeh L., Baghbani F., Shokrgozar MA., Allahyari Z., Preparation and characterization of novel functionalized multiwalled carbon nanotubes/chitosan/β-Glycerophosphate scaffolds for bone tissue engineering, Int. J. Biol. Macromolec., 97, 365-372, 2016. 4. Newman P., Minett A., Ellis-Behnke R., Zreiqat H., Carbon nanotubes: their potential and pitfalls for bone tissue regeneration and engineering Nanomed Nanotech Biol Med, 9, 1139-1158, 2013. 5. Lalwani G., Patel SC., Sitharaman B., Two-and three-dimensional all-carbon nanomaterial assemblies for tissue engineering and regenerative medicine, Ann Biomed Eng,44, 2020-2035, 2016. 6. Wu Z., Chen Z., Du X., Logan JM., Sippel J., Nikolou M., Kamaras K., Reynolds JR., Tanner DB., Hebard AF., and Rinzler AG., Transparent, conductive carbon nanotube films, Science, 305, 1273-1276, 2004. 7. Nayak TR., Jian L., Phua LC., Ho HK., Ren Y., Pastorin G., Thin films of functionalized multiwalled carbon nanotubes as suitable scaffold materials for stem cells proliferation and bone formation. ACS. Nano, 4, 7717-7725, 2010. 8. Khang D, Sato M., Price RL., Ribbe AE., Webster TJ., Selective adhesion and mineral deposition by osteoblasts on carbon nanofiber patterns, Int. J. Nanomed., 1, 65-72, 2006. 9. Stout DA., and Webster TJ., Carbon nanotubes for stem cell control, Mater. Today, 15, 312-318, 2012. 10. Elias KL., Price RL., Webster TJ., Enhanced functions of osteoblasts on nanometer diameter carbon fibers, Biomaterials, 23, 3279-3287, 2002. 11. Li X., Gao H., Uo M., Sato Y., Akasaka T., Abe S., Feng Q., Cui F., Watari F., Maturation of osteoblast-like SaoS2 induced by carbon nanotubes, Biomed. Mater., 4, 2008. 12. Tutak W., Chhowalla M., Sesti F., The chemical and physical characteristics of single-walled carbon nanotube film impact on osteoblastic cell response, Nanotechnology, 21, 315102, 2010. 13. Liu D., Yi C., Zhang D., Zhang J., Yang M., Inhibition of proliferation and differentiation of mesenchymal stem cells by carboxylated carbon nanotubes, ACS Nano, 4, 2185-2195, 2010. 14. Zanello LP., Zhao B., Hu H., Haddon RC., Bone cell proliferation on carbon nanotubes, Nano Lett., 6, 562-567, 2006. 15. Price RL., Waid MC., Haberstroh KM., Webster TJ., Selective bone cell adhesion on formulations containing carbon nanofibers, Biomaterials, 24, 1877-1887, 2003. 16. Mattioli-Belmonte M., Vozzi G., Whulanza Y., Seggiani M., Fantauzzi V., Orsini G., Ahluwalia A., Tuning polycaprolactone–carbon nanotube composites for bone tissue engineering scaffolds, Mater. Sci. Eng., C, 32, 152-159, 2012. 17. Nisbet DR., Forsythe JS., Shen W., Finkelstein DI., Horne MK., Review paper: a review of the cellular response on electrospun nanofibers for tissue engineering, J. Biomater. Appl, 24, 7-29, 2009. 18. Kumar S., Rani R., Dilbaghi N., Tankeshwar K., Kim KH., Carbon nanotubes: a novel material for multifaceted applications in human healthcare, Chem. Soc. Rev., 46, 158-196, 2017. 19. Ng R., Zang R., Yang KK., Liu N., Yang ST., Three-dimensional fibrous scaffolds with microstructures and nanotextures for tissue engineering, Rsc. Advances., 2, 10110-10124, 2012. 20. Han Z., Tay B., Tan C., Shakerzadeh M., Ostrikov K., Electrowetting control of Cassie-to-Wenzel transitions in superhydrophobic carbon nanotube-based nanocomposites, ACS Nano, 3, 3031-3036, 2009. 21. Lalwani G., Kwaczala AT., Kanakia S., Patel SC., Judex S., Sitharaman B., Fabrication and characterization of three-dimensional macroscopic all-carbon scaffolds, Carbon, 53,90-100, 2013. 22. Patel SC., Alam O., Zhang D., Grover K, Qin YX., Sitharaman B, Layer-by-layer, ultrasonic spray assembled 2D and 3D chemically crosslinked carbon nanotubes and grapheme, J MATER RES, 32, 370-382, 2016. 23. Tait JG., Worfolk BJ., Maloney SA., Hauger TC., Elias AL., Buriak JM., Harris KD., Spray coated high-conductivity PEDOT: PSS transparent electrodes for stretchable and mechanically-robust organic solar cells, Sol. Energ. Mat. Sol. Cells, 110, 98-106, 2013. 24. Shi X., Hudson JL., Spicer PP., Tour JM., Krishnamoorti R., Mikos AG. , Injectable nanocomposites of single-walled carbon nanotubes and biodegradable polymers for bone tissue engineering, Biomacromolecules, 7, 2237-2242, 2006. 25. Lin C., Wang Y., Lai Y., Yang W., Jiao F., Zhang H., Ye S., Zhang Q., Incorporation of carboxylation multiwalled carbon nanotubes into biodegradable poly(lactic-co-glycolic acid) for bone tissue engineering, Colloids Surf., B, 83, 367-375, 2011. 26. Da Silva EE., Della Colleta HH., Ferlauto AS., Moreira RL., Resende RR., Oliveira S., Kitten GT., Lacerda RG., Ladeira LO., Nanostructured 3-D collagen/nanotube biocomposites for future bone regeneration scaffolds, Nano Res., 2, 462-473, 2010. 27. 46. Hirata E., Uo M., Takita H., Akasaka T., Watari F., Yokoyama A., Multiwalled carbon nanotube-coating of 3D collagen scaffolds for bone tissue engineering, Carbon, 49, 3284-3291, 2011. 28. Wang SF., Shen L., Zhang WD., Tong YJ., Preparation and mechanical properties of chitosan/ carbon nanotubes composites, Biomacromolecules, 6, 3067-3072, 2005. 29. Depan D., Misra RD., Processing–structure– functional property relationship in organic–inorganic nanostructured scaffolds for bone-tissue engineering: The response of preosteoblasts, J. Biomed. Mater. Res., Part A, 100, 3080-3091, 2012. 30. Shin SR., Bae H., Cha JM., Mun JY., Chen YC., Tekin H., Shin H., Farshchi S, Dokmeci MR., Tang S., Khademhosseini A., Carbon nanotube reinforced hybrid microgels as scaffold materials for cell encapsulation, ACS Nano, 6, 362-372, 2012. -masumemasudi12192017273610.66224/irdpt.27512.2.3.27http://irdpt.ir/fa/Article/27512http://irdpt.ir/fa/Article/Download/27512http://irdpt.ir/fa/Article/Download/27512http://irdpt.ir/fa/Article/Download/27512http://irdpt.ir/fa/Article/Download/27512http://irdpt.ir/fa/Article/Download/27512http://irdpt.ir/fa/Article/Download/27512http://irdpt.ir/fa/Article/Download/275121. فرهادیار،نازنین،سنتزوبررسیخواصپوشش¬هایهیبریدینانوکامپوزیتیبرپایهاپوکسی-سیلیس، پژوهشکدهعلوم،پژوهشگاهپلیمروپتروشیمیایران،1383 2. زندی زند، روح انگیز،بررسی مقاومت در برابر خوردگی،سایشوهوازدگیدرپوشش¬های هیبریدینانوکامپوزیتیبرپایهاپوکسی-سیلیسبهوسیلهروش¬های اسپکتروفوتومتری، پژوهشکده علوم، پژوهشگاه پلیمروپتروشیمیایران،1383. 3. Lebaron P. C., Wang Z., Pinnavaia T. J., Polymer-layered Silicate Nanocomposites: an Overview , Applied clay science, Elsevier, 15, 1, 11-29, 1999. 4. Figueira R. B., Silva C. J. R., Pereira E. V., Organic-inorganic Hybrid Sol-gel Coatings for Metal Corrosion Protection: AReview of Recent Progress , Journal of Coatings Technology and Research, 12, 1, 1-35, 2014. 5. Arcos D., Vallet-regí M., Acta Biomaterialia Sol-gel Silica-based Biomaterials and Bone Tissue Regeneration , Acta Biomaterialia, 6, 8, 2874-2888, 2010. 6. Podbielska H., Za A. U., Sol-gel Technology for Biomedical Engineering, Bulletin of the Polish Academy of Sciences Technical Sciences, 53, 261-271, 2005. 7. González-garcía Y., Mol J. M. C., Muselle T., Graeve I. De, Assche G. Van, Scheltjens G., A Combined Mechanical, Microscopic and Local Electrochemical Evaluation of Self-healing Properties of Shape-memory Polyurethane Coatings ,Electrochimica Acta, 56, 9619-9626,2011. 8. سروری،هانیه،تهیهپوشش¬های سیلیکونیبرایاستفادهدرسامانه¬های دارورسانی خوراکی، پژوهشکده علوم، پژوهشگاه پلیمروپتروشیمیایران،1390 9. قدیمیحرفه،فائزه،تهیهوشناساییپوشش¬های نانوکامپوزیتیمقاومبهسایشبرپایهاکسیدهایفلزی، پژوهشکده علوم، پژوهشگاه پلیمروپتروشیمیایران،1392 10. ارشاد لنگرودی،ا., رحیمیا., مقدمهایبرپوششهایهیبریدینانوکامپوزیتی , پژوهشگاهعلوموفناوریرنگ،نقشبیان, 1388 11. http://www.tebyan.net/newindex.aspxpid=289778. 12. Suleiman R., Khaled M., Wang H., Smith T. J., Gittens J., Akid R. et al., Comparison of Selected Inhibitor Doped Sol-gel Coating Systems for Protection of Mild Steel ,Corrosion Engineering, Science and Technology, 49, 189-196, 2014. 13. Samide, A., Thermal Behaviour and Adsorption Properties of Some Benzothiazole Derivatives,Journal of Thermal Analysis and Calorimetry, 118, 651-659,2014. 14. Zheludkevich M. L., Salvado I. M., Ferreira M. G. S., Sol-gel Coatings for Corrosion Protection of Metals , Journal of Materials Chemistry, 15, 48, 5099, 2005. 15. Zheng S., Li J., Inorganic - organic Sol-gel Hybrid Coatings for Corrosion Protection of Metals , Sol-Gel Sci ence Technology, 54, 2010, 174-187, 2010. 16. Khramov A. N., Balbyshev V. N., Voevodin N. N., Donley M. S., Nanostructured Sol-gel Derived Conversion Coatings Based on Epoxy- and Amino-silanes, Progress in Organic Coatings, 47, 207-213, 2003. 17. Zha F., Lu R. H., Determination of Thermodynamic and Kinetic Parameters of Inclusion Complex Formation of 2-mercaptobenzothiazole with Beta-cyclodextrin, Polish Journal of Chemistry, 79, 9, 1461-1467, 2005. 18. Basu B. J., Srinivasan A., Manasa J., Grips V. K. W., Improved Corrosion Protection of Aluminium Alloy AA 2024 by Sol-gel Hybrid Coatings After Surface Pretreatment by Silanisation , Surface Engineering, 28, 294-299, 2012. 19. Liu G., Zeng H., Lu Q., Zhong H., Choi P., Xu Z., Adsorption of Mercaptobenzoheterocyclic Compounds on Sulfide Mineral Surfaces: A Density Functional Theory Study of Structure-reactivity Relations , Colloids and Surfaces A: Physicochemical and Engineering Aspects, Elsevier B.V., 409, 1-9, 2012. 20. Khramov a. N., Voevodin N. N., Balbyshev V. N., Mantz R. a., Sol-gel-derived Corrosion-protective Coatings with Controllable Release of Incorporated Organic Corrosion Inhibitors , Thin Solid Films, 483, 1-2, 191-196, 2005. 21. Abdolah Zadeh M., van der Zwaag S., Garcia S. J., Routes to Extrinsic and Intrinsic Self-healing Corrosion Protective Sol-gel Coatings: AReview , Self-Healing Materials, 1, 1-18, 2013. 22. Steinha S., Cost-efficient Conversion Coatings for Corrosion Protection Prepared by the Sol-gel Process , 2-7, 2008. 23. Capelossi V. R., Poelman M., Recloux I., Hernandez R. P. B., Melo H. G. De, Olivier M. G., Electrochimica Acta Corrosion Protection of Clad 2024 Aluminum Alloy Anodized in Tartaric-sulfuric Acid Bath and Protected with Hybrid Sol-gel Coating , Electrochimica Acta, Elsevier Ltd, 124, 69-79, 2014. 24. Khelifa F., Druart M., Habibi Y., Bénard F., Leclère P., Olivier M. et al., Progress in Organic Coatings Sol -gel Incorporation of Silica Nanofillers for Tuning the Anti-corrosion Protection of Acrylate-based Coatings, Progress in Organic Coatings, Elsevier B.V., 76, 5, 900-911,2013. 25. Roussi E., Tsetsekou A., Skarmoutsou A., Charitidis C. A., Karantonis A., Anticorrosion and Nanomechanical Performance of Hybrid Organo-silicate Coatings Integrating Corrosion Inhibitors, Surface and Coatings Technology, Elsevier B.V., 232, 2013, 131-141, 2013. 26. Khramov a. N., Voevodin N. N., Balbyshev V. N., Donley M. S., Hybrid Organo-Ceramic Corrosion Protection Coatings with Encapsulated Organic Corrosion Inhibitors , Thin Solid Films, 447-448, 549-557, 2004. 27. Zandi-zand R., Ershad-langroudi A., Rahimi A., Silica Based Organic-inorganic Hybrid Nanocomposite Coatings for Corrosion Protection ,Progress in Organic Coatings,53, 286-291, 2005. 28. CarneiroJ.,TedimJ.,FerreiraM.G. S. Chitosanasasmart Coatingfor Corrosion Protectionof Aluminumalloy2024:A Review.,Prog Org Coatings., 89, 348-356,2015. 29. ChawadaG., DholakiyaB. Z., Influenceof Organic Corrosion Inhibitorsonthe Corrosion Performanceof Organic–inorganic Hybrid Coating SappliedonAluminium alloy., Res Chem Intermed., 42, 545-577,2016. 30. MonikaS., MWalczak M.,Gil M.P.,Belashehr T.,Kousar K.,Lozada P.A.,Lindsay R., DeterminingtheChemicalCompositionofCorrosionInhibitor/MetalInterfaceswithXPS:MinimizingPostImmersionOxidation,Journal of Visualized Experiments,121,2017.-mohsenabbasi12192017374810.66224/irdpt.27513.2.3.37http://irdpt.ir/fa/Article/27513http://irdpt.ir/fa/Article/Download/27513http://irdpt.ir/fa/Article/Download/27513http://irdpt.ir/fa/Article/Download/27513http://irdpt.ir/fa/Article/Download/27513http://irdpt.ir/fa/Article/Download/27513http://irdpt.ir/fa/Article/Download/27513http://irdpt.ir/fa/Article/Download/275131.Rezadoust A.M.,Beheshti M.H., Reinforced Plastics (Polymer Composites) (Persian). Iran Polymer and Petrochemical Institute, Tehran, Iran, 3-4,2005. 2.Odegard G.M., Bandyopadhyay A., “Physical Aging of Epoxy Polymers and their Composites” J. Polym. Sci. Part B: Polym. Phys., 49, 1695‐1716, 2011. 3.Martin R., Ageing of Composites, Woodhead Publishing Limited, Cambridge, England, 467-496, 2008. 4.Tian W.D., Hodgkin J., “Long-term Aging in a Commercial Aerospace Composite Sample: Chemical and Physical Changes”J. Appl. Polym. Sci., 115, 2981-2985, 2010. 5.Hutchinson J.M., “Physical Aging of Polymers”Prog. Polym.Sci, 20, 703-760,1995. 6. Brown R.P., Greenwood J.H., Particle Guide to the Assessment of the Useful Life of Plastics, Rapra Technology Limited, Shrewsbury,UK,15-20, 2002. 7. Wright D.C., Environmental Stress Cracking of Plastics, Rapra Technology Limited, Shrewsbury,UK,4-7, 1996. 8. Maxwell A.S., Broughton W.R., Dean G., Sims G.D., Review of Accelerated Ageing Methods and Lifetime Prediction Techniques for Polymeric Materials, National Physical Laboratory (NPL), Teddington,UK, 10-13,2005. 9. Sims G.D., Broughton W.R., Glass Fiber Reinforced Plastics–Properties, National Physical Laboratory, Teddington, UK, 151-197, 2000. 10. BankL.C., GentryT.R., “Accelerated Test Methods to Determine the Long-Term Behavior of FRP Composite Structures: Environmental Effects”J. Reinf. Plast.Comp., 14, 559-587,1995. 11. Amin M., Akbar M., Salman M.,“Composite Insulators and Their Aging: An Overview”Sci. China Ser. E, 50, 697-713, 2007. 12. Kim S.H., Cherney E.A., Hackam R., Rutheford K.G.,“Chemical Changes at the Surface of RTV Silicone Rubber Coatings on Insulators during Dry-Band Arcing”Ieee T. Dielect. El. In., 1, 106-123, 1994. 13. Sarathi R., Chandrasekar S., Giri V.S.,Venkataseshaiah C., Velmurugan R., “Analysis of Surface Degradation of High Density Polyethylene (HDPE) Insulation Material due to Tracking”B. Mater. Sci.,27, 251-262, 2004. 14. Hu H.W., “Physical Aging in Long Term Creep of Polymeric Composite Laminates”J. Mech., 23, 245-252, 2007. 15. Shi X.D., Fernando B.M.D., CrollSG., “Concurrent Physical Aging and Degradation of Crosslinked Coating Systems in Accelerated Weathering”J. Coat. Technol. Res, 5, 299-309, 2008. 16. Leveque D., Schieffer A., Mavel A., Maire J.F.,“Analysis of How Thermal Aging Affects the Long-Term Mechanical Behavior and Strength of Polymer–Matrix Composites”Compos. Sci. Technol.,65, 395-401, 2005. 17. G'sell C., Mckenna G.B., “Influence of Physical Ageing on the Yield Response of Model DGEBA/Poly(propylene oxide) Epoxy Glasses”Polymer, 33, 2103-2113, 1992. 18. Oyanguren P.A., Vallo C.I., Frontini P.M., Williams R.J.J., “Rejuvenation of Epoxy Glasses Subjected to Uniaxial Compression”Polymer, 35, 5279-5282, 1994. 19. Kong E.S.W., “Physical Aging in Epoxy Matrices and Composites”Adv. Polym. Sci., 80, 125-171, 1986. 20. Aboulfaraj M., Gsell C., Mangelinck D., McKenna G.B., “Physical Aging of Epoxy Networks After Quenching and/or Plastic Cycling”J. Non-Cryst.Solids, 172, 615-621, 1994. 21. Chang T.D., Brittain J.O., “Studies of Epoxy Resin Systems: Part C: Effect of Sub-Tg Aging on the Physical Properties of a Fully Cured Epoxy Resin”Polm. Eng. Sci., 22, 1221-1227, 1982. 22.Ophir Z.H., Emerson J.A., Wilkes G.L., “Sub‐Tg Annealing Studies of Rubber‐Modified and Unmodified Epoxy Systems”J. Appl. Physics, 49, 5032-5038, 1978. 23. Kawakami H., Souda K., Nanzai Y., “Relaxation Phenomenon in Epoxy Glass Aged under Post-Yield Strain”Polym. Eng. Sci., 46, 630-634, 2006. 24. Kawakami H., Watanabe M., “Changes in the Thermomechanical Behavior of Epoxy Glasses Under the State of Strain Aging”J. Appl. Polym. Sci.,107, 2095-2100, 2008. 25. FergusonT.P., Qu J., “Elastic Modulus Variation due to Moisture Absorption and Permanent Changes Upon Redrying in an Epoxy Based Underfill”IEEE T. Compon. Pack.T., 29, 105-111, 2006. 26. Barbosa A.P.C., Fulco A.P.P., Guerra E.S.S., Arakaki F.K, Tosatto M., Costa M.C.B., Melo J.D.D., “Accelerated Aging Effects on Carbon Fiber/Epoxy Composites”Compos.Part B-Eng., 110, 298-306, 2017. 27. Sugiman S., Putra I.K.P., Setyawan P.D., “Effects of the Media and Ageing Condition on the Tensile Properties and Fracture Toughness of Epoxy Resin”Polym. Degrad. Stabil.,134, 311-321, 2016. 28. Kwon D.J., Shin P-S., Kim J-H., Baek Y-M., Park H-S, Devries L., Park J-M., “Interfacial Properties and Thermal Aging of Glass Fiber/Epoxy Composites Reinforced with SiC and SiO2 Nanoparticles”Compos. Part B-Eng., 130, 46-53, 2017. 29. Chang L.N., Chow W.S., “Accelerated Weathering on GlassFiber/Epoxy/Organo-MontmorilloniteNanocomposites”J. Compos.Mater, 24, 1421-1434, 2010. 30. Li. Y., Xue B., “Hydrothermal Ageing Mechanisms of Unidirectional Flax Fabric Reinforced Epoxy Composites”Polym. Degrad. Stabil.,126, 144-158, 2016.-Ahmad RezaBahramian12192017495610.66224/irdpt.27514.2.3.49http://irdpt.ir/fa/Article/27514http://irdpt.ir/fa/Article/Download/27514http://irdpt.ir/fa/Article/Download/27514http://irdpt.ir/fa/Article/Download/27514http://irdpt.ir/fa/Article/Download/27514http://irdpt.ir/fa/Article/Download/27514http://irdpt.ir/fa/Article/Download/27514http://irdpt.ir/fa/Article/Download/27514 1.Zhang, G.H., BonS.A., . ZhaoC.-Y,Synthesis, Characterization and Thermal Properties of Novel Nanoencapsulated Phase Change Materials for Thermal Energy Storage. Solar Energy, 1149-1154,2012. 2. Latibari S.T., Synthesis, Characterization and Thermal Properties of Nanoencapsulated Phase Change Materials Via Sol–gel Method,Energy, 664-672,2013. 3. ShannaqAl, Farid,Mic R. M., Roencapsulation of Phase Change Materials (PCMs) for Thermal Energy Storage Systems,Advancesin Thermal Energy Storage Systems.Methods and Applications, 247-284,2014. . 4. Chen, C., GuoH, LioY, WangC, A New Kind of Phase Change Material (PCM) for Energy-storing Wallboard,Energy and Buildings, 882-890,2008. 5. Huang, M., EamesP., EwittN., TheApplication of a Validated Numerical Model to Predict the Energy Conservation Potential of Using Phase Change Materials in the Fabric of a Building,Solar Energy Materials and Solar Cells,1951-1960,2006.. 6. Sarı, A., AlkaneC, BicerA, Altuntas A, Bihgin C,Micro/nanoencapsulated n-Nonadecane with Poly (Methyl methacrylate) Shell for Thermal Energy Storage,Energy Conversion and Management, 614-621,2014. 7. Kwetta, D.N., Haghighat F.,Thermal Energy Storage with Phase Change Material a State ofthe Art Review, Sustainable Cities and Society, 87-100,2014. 8. Yu, F., ChenZH, ZengXR, GaoXN,Poly (Methyl Methacrylate) Copolymer Nanocapsules Containing Phase‐change Material (N‐dodecanol) Prepared Via Miniemulsion Polymerization,Journal of Applied Polymer Science, 551-556,2015. 9. Do, T., KoYG, ChanY, ChoiUS, Encapsulation of Phase Change Material with Water-absorbable Shell for Thermal Energy Storage,ACS Sustainable Chemistry & Engineering,2874-2881,2015. 10. Cheng R.,PomiomowskiM.,WangX,A New Method to Determine Thermophysical Properties of PCM-Concrete Brick,Applied energy,988-998,2013. 11. Su, W., J. Darkwa,G. Kokogiannakis,Review of Solid–Liquid Phase Change Materials and Their Encapsulation Technologies, Renewable and Sustainable Energy Reviews, 373-391,2015. 12. Konuklu Y., PaksoyH.O., UnalM., Nanoencapsulation of N-alkanes with Poly (Styrene-co-ethylacrylate) Shells for Thermal Energy Storage. Applied Energy, 335-340,2015. 13. Mohammadi B., NagafiFS., RanjbarH., MohammadiJ.,ZakaryazadehM.,Nanoencapsulation of Butyl Palmitate in Polystyrene-co-methyl Methacrylate Shell for Thermal Energy Storage Application,Energy and Buildings, 99-105,2016. 14. Fuensanta, M., Paiphansiri U., Romero MO., Thermal Properties of a Novel Nanoencapsulated Phase Change Material for Thermal Energy Storage,Thermochimica Acta,95-101,2013. 15. Fang, Y., YuH., WanW., GaoX., Preparation and Thermal Performance ofPolystyrene/n-tetradecane Composite Nanoencapsulated Cold Energy Storage Phase Change Materials,Energy Conversion and Management, 430-436, 2013.-yousefjahani12192017576610.66224/irdpt.27515.2.3.57http://irdpt.ir/fa/Article/27515http://irdpt.ir/fa/Article/Download/27515http://irdpt.ir/fa/Article/Download/27515http://irdpt.ir/fa/Article/Download/27515http://irdpt.ir/fa/Article/Download/27515http://irdpt.ir/fa/Article/Download/27515http://irdpt.ir/fa/Article/Download/27515http://irdpt.ir/fa/Article/Download/275151. Biesenberger J. A. and Gogos C. G., Reactive Polymer Processing,” Polym. Eng. Sci., 20, 838–846, 1980. 2. Xanthos M., Reactive Extrusion: Principles and Practice, Hanser Publishers, Germany, 304, 1992. 3. Kamal M. R. and Ryan M. E., Reactive Polymer Processing: Techniques and Trends,” Adv. Polym. Tecl., 4, 323–348, 1984. 4. Rauwendaal C., Polymer Extrusion. Carl Hanser Verlag GmbH Co KG, 2014. 5. Saldivar-Guerra E. and Vivaldo-Lima E., Handbook of Polymer Synthesis, Characterization, and Processing. John Wiley & Sons, 2013. 6. Tzoganakis C., Reactive Extrusion of Polymers : A Review. Adv. Polym. Tech., 9, 321-330, 1989. 7. Raquez J., Narayan R., and Dubois P., Recent Advances in Reactive Extrusion Processing of Biodegradable Polymer-Based Compositions, Macromol. Mater, Eng., 447–470, 2008. 8. Al-Malaika S., Reactive Modifiers for Polymers. Springer Science &Business Media, 2012. 9. Dean Shi Q. S. and Yin J., Preparation of Functional and Reactive Polyolefin as Well as Their Application, React. Funct. Polym. Res. Adv., 2008. 10. Passaglia E., Coiai S., and Augier S., Control of Macromolecular Architecture During the Reactive Functionalization in the Melt of Oolefin Polymers,” Prog. Polym. Sci., 34, 911–947, 2009. 11. Barroso M. Reactive and Functional Polymers Research Advances.,Nova publishers, 2007. 12. G. Beyer and C. Hopmann, Reactive Extrusion: Principles and Applications. Wiley, 2017. 13. Ortiz Rodríguez E., Numerical Simulations of Reactive Extrusion in Twin Screw Extruders,University of Waterloo, 2010. 14. Fink J. K., Reactive Polymers Fundamentals and Applications: a Concise Guide to Industrial Polymers. William Andrew, 2013. 15. Bettini S. H. P. and Agnelli J. A. M., Grafting of Maleic Anhydride onto Polypropylene by,” J. Appl. Polym. Sci., 2706–2717, 2002. 16. Bettini S. H. P., de Mello L. C., Muñoz P. A., and RuvoloFilho A., Grafting of Maleic Anhydride onto Polypropylene, in the Presence and Absence of Styrene, for Compatibilization of Poly (Ethylene Terephthalate)/(Ethylene–Propylene) Blends,” J. Appl. Polym. Sci., 127, 1001–1009, 2013. 17. Wenzel C. B., De Groot H. J. M., and Lugtenburg J., 13 CNMR Study of the Grafting of Maleic Anhydride onto Polyethene , Polypropene , and Ethene-Propene Copolymers,Macromolecules, 29, 1151–1157, 1996. 18. Bray T., Damiris S, Grace A., Moad G, O'Shea M., Ezio Rizzardo, and Gary Van Diepen “Developments in the Synthesis of Maleated Polyolefins by Reactive Extrusion,” Macromol. Symp., 129, 109–118,1998. 19. Jantanasakulwong K., Leksawasdi N., Seesuriyachan P., Wongsuriyasak S., Techapun C., and Ougizawa T., Reactive Blending of Thermoplastic Starch and Polyethylene-graft-Maleic Anhydride with Chitosan as Compatibilizer,” Carbohyd. Polym., 153, 89–95, 2016. 20. Ma, D., Zhao D., Zhao J., Du S., Pang J., Wang W., and Fan C., Functionalization of Reclaimed Polyethylene with Maleic Anhydride and its Application in Improving the High Temperature Stability of Asphalt Mixtures, Constr. Build. Mater., 113, 596–602, 2016. 21. Kim T. H. and Lee N. G., Melt-Grafting of Maleimides Having Hindered Phenol Group onto Polypropylene,” Bull. Korean Chem. Soc., 24, 1809–1813, 2003. 22. Rosales C., Perera R., Ichazo M., Gonzalez J., Rojas H., Sanchez A., and Diaz Barrios A., Grafting of Polyethylenes by Reactive Extrusion. Influence on the Molecular Structure,” J. Appl. Polym. Sci., 70, 161–176, 1998. 23. Zhang M., Duhamel J., Van Duin M., and Meessen P., Characterization by Fluorescence of the Distribution of Maleic Anhydride Grafted onto Ethylene− Propylene Copolymers, Macromolecules, 37, 1877–1890, 2004. 24. Liu N. C., Xie H. Q., and Baker W. E., Comparison of the Effectiveness of Different Basic Functional Groups for the Reactive Compatibilization of Polymer Blends,” Polymer, 34, 4680–4687, 1993. 25. Al-Malaika S. and Eddiyanto E., Reactive Processing of Polymers: Effect of Bifunctional and Tri-Functional Comonomers on Melt Grafting of Glycidyl Methacrylate onto Polypropylene,” Polym. Degrad. Stab., 95, 353–362, 2010. 26. Liu N. C. and Baker W. E., Basic Functionalization of Polypropylene and the Role of Interfacial Chemical Bonding in its Toughening,” Polymer, 35, 988–994, 1994. 27. Vainio T., Hu G., Lambla M., and Seppälä J., Functionalization of Polypropylene with Oxazoline and Reactive Blending of PP with PBT in a Corotating twin Screw Extruder,” J. Appl. Polym. Sci., 63, 883–894, 1997. 28. Matsumura A. and Nishiguchi M., Heat-resistant Silane Crosslinked Resin Molded Body and Method of Producing the Same, Heat-resistant Silane Crosslinkable Resin Composition and Method of Producing the Same, Silane Master Batch, and Heat-resistant Product Using Heat-resistant Silane Crosslinked Resin Molded Body., Google Patents, 2016. 29. Forsyth J. C., Baker W. E., Russell K. E., and Whitney R. A., Peroxide-Initiated Vinylsilane Grafting: Structural Studies on a Hydrocarbon Substrate,” J. Polym. Sci. Part A Polym. Chem., 35, 3517–3525, 1997. 30. Burton E., Woodhead M., Coates P., and Gough T., Reactive Grafting of Glycidyl Methacrylate onto Polypropylene,” J. App. Polym. Sci., 117, 2707-2714, 2010. -سید مرتضینقیب12192017676610.66224/irdpt.27516.2.3.67http://irdpt.ir/fa/Article/27516http://irdpt.ir/fa/Article/Download/27516http://irdpt.ir/fa/Article/Download/27516http://irdpt.ir/fa/Article/Download/27516http://irdpt.ir/fa/Article/Download/27516http://irdpt.ir/fa/Article/Download/27516http://irdpt.ir/fa/Article/Download/27516http://irdpt.ir/fa/Article/Download/275161. Bajaj M., Winter J., and Gallert C., Effect of Deproteination and Deacetylation Conditions on Viscosity of Chitin and Chitosan Extracted from Crangon Crangon Shrimp Waste, Biochemical Engineering Journal, 56, 51-62, 2011. 2. Bernkop-Schnürch A., and Dünnhaupt S., Chitosan-based Drug Delivery Systems, European Journal of Pharmaceutics and Biopharmaceutics, 81, 463-469, 2012. 3. Vaghari H., Jafarizadeh-Malmiri H., Berenjian A., and Anarjan, N., Recent Advances in Application of Chitosan in Fuel Cells, Sustainable Chemical Processes, 1, 16, 2013. 4. Pillai C. K. S., Paul W., and Sharma C. P., Chitin and Chitosan Polymers: Chemistry, Solubility and Fiber Formation, Progress in Polymer Science, 34, 641-678, 2009. 5. Prabaharan M ,. Chitosan Derivatives as Promising Materials for Controlled Drug Delivery, Journal of Biomaterials Applications, 23, 5-36, 2008. 6. Al Sagheer F. A., Al-Sughayer M. A., Muslim S., and Elsabee M. Z., Extraction and Characterization of Chitin and Chitosan from Marine Sources in Arabian Gulf, Carbohydrate Polymers, 77, 410-419, 2009. 7. Ohya Y., Shiratani M., Kobayashi H., and Ouchi T., Release Behavior of 5-fluorouracil from Chitosan-gel Nanospheres Immobilizing 5-fluorouracil Coated with Polysaccharides and their Cell Specific Cytotoxicity, Journal of Macromolecular Science—Pure and Applied Chemistry , 31, 629-642, 1994. 8. Wang J. J., Zeng Z. W., Xiao R. Z., Xie T., Zhou G. L., Zhan X. R., and Wang S. L., Recent Advances of Chitosan Nanoparticles as Drug Carriers, International Journal of Nanomedicine, 6, 765, 2011. 9. Agnihotri S. A., Mallikarjuna N. N., and Aminabhavi T. M., Recent Advances on Chitosan-based Micro-and Nanoparticles in Drug Delivery, Journal of Controlled Release, 100, 5-28, 2004. 10. Grenha A., Chitosan Nanoparticles: a Survey of Preparation Methods, Journal of drug targeting, 20, 291-300, 2012. 11. Berthold A., Cremer K., and Kreuter J. S. T. P., Preparation and Characterization of Chitosan Microspheres as Drug Carrier for Prednisolone Sodium Phosphate as Model for Anti-inflammatory Drugs, Journal of Controlled Release , 39, 17-25, 1996. 12. Estevinho B. N., Rocha F., Santos L., and Alves A., Microencapsulation with Chitosan by Spray Drying for Industry Applications–A review, Trends in Food Science & Technology, 31, 138-155, 2013. 13. Mitra S., Gaur U., Ghosh P. C., and Maitra A. N., Tumour Targeted Delivery of Encapsulated Dextran–Doxorubicin Conjugate Using Chitosan Nanoparticles as Carrier, Journal of Controlled Release, 74, 317-323, 2001. 14. Calvo P., Remunan‐Lopez C., Vila‐Jato J. L., and Alonso M. J., Novel Hydrophilic Chitosan‐Polyethylene Oxide Nanoparticles as Protein Carriers, Journal of Applied Polymer Science, 63, 125-132, 1997. 15. Anandhakumar S., Krishnamoorthy G., Ramkumar K. M., and Raichur A. M., Preparation of Collagen Peptide Functionalized Chitosan Nanoparticles by Ionic Gelation Method: An Effective Carrier System for Encapsulation and Release of Doxorubicin for Cancer Drug Delivery, Materials Science and Engineering: C, 378-385, 2017. 16. Xu J. H., Li S. W., Tostado C., Lan W. J., and Luo G. S., Preparation of Monodispersed Chitosan Microspheres and in Situ Encapsulation of BSA in a co-axial Microfluidic Device, Biomedical Microdevices, 11, 243-249, 2009. 17. Xu J., Xu X., Zhao H., and Luo G., Microfluidic Preparation of Chitosan Microspheres with Enhanced Adsorption Performance of Copper (II), Sensors and Actuators B: Chemical, 183, 201-210, 2013. 18. Yang C. H., Huang K. S., Lin P. W., and Lin Y. C. Using a Cross-flow Microfluidic Chip and External Crosslinking Reaction for Monodisperse TPP-Chitosan Microparticles. Sensors and Actuators B: Chemical, 124, 510-516, 2007. 19. Xu J. H., Zhao H., Lan W. J., and Luo G. S. A novel Microfluidic Approach for Monodispersed Chitosan Microspheres with Controllable Structures, Advanced Healthcare Materials, 1, 106-111, 2012. 20. Widder K. J., Senyei A. E., and Scarpelli D. G., Magnetic Microspheres: A Model System for Site Specific Drug Delivery in Vivo, Proceedings of the Society for Experimental Biology and Medicine, 158, 141-146, 1978. 21. Elmizadeh H., Khanmohammadi M., Ghasemi K., Hassanzadeh G., Nassiri-Asl, M., and Garmarudi A. B., Preparation and Optimization of Chitosan Nanoparticles and Magnetic Chitosan Nanoparticles as Delivery Systems Using Box–Behnken Statistical Design, Journal of Pharmaceutical and Biomedical Analysis, 80, 141-146, 2013. 22. Reddy D. H. K., and Lee S. M., Application of Magnetic Chitosan Composites for the Removal of Toxic Metal and Dyes from Aqueous Solutions, Advances in Colloid and Interface Science, 201, 68-93, 2013. 23. Karimi Z., Abbasi S., Shokrollahi H., Yousefi G., Fahham M., Karimi L., and Firuzi O., Pegylated and Amphiphilic Chitosan Coated Manganese Ferrite Nanoparticles for pH-sensitive Delivery of Methotrexate: Synthesis and Characterization, ‎ Materials Science and Engineering: C, 71, 504-511, 2017. 24. Montha W., Maneeprakorn W., Buatong N., Tang I. M., and Pon-On W., Synthesis of Doxorubicin-PLGA Loaded Chitosan Stabilized (Mn, Zn) Fe2O4 Nanoparticles: Biological Activity and pH-Responsive Drug Release, ‎ Materials Science and Engineering: C, 59, 235-240, 2016. 25. Huang H., Yuan Q., and Yang X., Preparation and Characterization of Metal–Chitosan Nanocomposites, Colloids and surfaces B: Biointerfaces, 39, 31-37, 2004. 26. Yadollahi M., Farhoudian S., and Namazi H., One-pot Synthesis of Antibacterial Chitosan/Silver Bio-Nanocomposite Hydrogel Beads as Drug Delivery systems, International Journal of Biological Macromolecules, 79, 37-43, 2015. 27. Kumari S., and Singh R. P., Glycolic Acid-g-Chitosan-Gold Nanoflower Nanocomposite Scaffolds for Drug Delivery and Tissue Engineering, International journal of Biological Macromolecules, 50, 878-883, 2012. 28. Pramanik A., Laha D., Dash S. K., Chattopadhyay S., Roy S., Das D. K., ... and Karmakar P., An in-vivo Study for Targeted Delivery of Copper-Organic Complex to Breast Cancer Using Chitosan Polymer Nanoparticles, ‎ Materials Science and Engineering: C, 68, 327-337, 2016. 29. Zhang H., Yan T., Xu S., Feng S., Huang D., Fujita M., and Gao X. D., Graphene Oxide-Chitosan Nanocomposites for Intracellular Delivery of Immunostimulatory CpG Oligodeoxynucleotides, ‎ Materials Science and Engineering: C, 73, 144-151, 2017. 30. Singh R. P., Sharma G., Singh S., Bharti S., Pandey B. L., Koch B., and Muthu M. S., Chitosan-Folate Decorated Carbon Nanotubes for Site Specific Lung Cancer Delivery, Materials Science and Engineering: C, 77, 446-458, 2017.