Have a personal or library account? Click to login
Leading-Edge Polymer/Carbonaceous Nano-Reinforcement Nanocomposites—Opportunities for Space Sector Cover

Leading-Edge Polymer/Carbonaceous Nano-Reinforcement Nanocomposites—Opportunities for Space Sector

Advances in Materials Science
Volume 23 (2023): Issue 4 (December 2023)
By: Ayesha Kausar and  Ishaq Ahmad  
Open Access
|Dec 2023

References

  1. Kausar, A., Innovations in poly (vinyl alcohol) derived nanomaterials. Advances in Materials Science, 2020. 20(3): p. 5-22.
    Search in Google ScholarBack to article
  2. Cuellar, C., K. Watson, and E. Smela, Fabrication, characterization, and repair of nanocarbon-loaded aircraft paint-based sensors for real-world SHM: studies at the laboratory scale. Structural Health Monitoring, 2023: p. 14759217231198015.
    Search in Google ScholarBack to article
  3. Kausar, A., Advances in carbon fiber reinforced polyamide-based composite materials. Advances in Materials Science, 2019. 19(4): p. 67-82.
    Search in Google ScholarBack to article
  4. Kausar, A., et al., Graphene Nanocomposites in Space Sector—Fundamentals and Advancements. C, 2023. 9(1): p. 29.
    Search in Google ScholarBack to article
  5. Esteves, R., et al. Investigation of Stress Corrosion Cracking via in-situ Measurements. in AIAA SCITECH 2023 Forum. 2023.
    Search in Google ScholarBack to article
  6. El Khatiri, W., et al., Experimental study of component-based transfer path analysis hybrid methods applied to a helicopter. Applied Acoustics, 2023. 210: p. 109431.
    Search in Google ScholarBack to article
  7. Kannan, S., et al., Nanotechnology: Nanocomposites Processing, in Innovative Development in Micromanufacturing Processes. CRC Press. p. 372-392.
    Search in Google ScholarBack to article
  8. Weerasinghe, J., et al., Carbon Nanocomposites in Aerospace Technology: A Way to Protect Low-Orbit Satellites. Nanomaterials, 2023. 13(11): p. 1763.
    Search in Google ScholarBack to article
  9. Almajid, A., et al., Effects of graphene and CNT on mechanical, thermal, electrical and corrosion properties of vinylester based nanocomposites. Plastics, Rubber and Composites, 2015. 44(2): p. 50-62.
    Search in Google ScholarBack to article
  10. Li, M., I.H. Kim, and Y.G. Jeong, Cellulose acetate/multiwalled carbon nanotube nanocomposites with improved mechanical, thermal, and electrical properties. Journal of Applied Polymer Science, 2010. 118(4): p. 2475-2481.
    Search in Google ScholarBack to article
  11. Thomas, S., S.C. George, and S. Thomas, Evaluation of mechanical, thermal, electrical, and transport properties of MWCNT-filled NR/NBR blend composites. Polymer Engineering & Science, 2018. 58(6): p. 961-972.
    Search in Google ScholarBack to article
  12. Park, S.M., M.H. Kim, and O.O. Park, Synergistic effect of carbon nanotubes on the flame retardancy of poly (methyl methacrylate)/zinc oxalate nanocomposites. Macromolecular Research, 2016. 24(9): p. 777-781.
    Search in Google ScholarBack to article
  13. Kausar, A., Multifunctional polymer/carbonaceous nanocomposites for aerospace applications. Polymeric Nanocomposites with Carbonaceous Nanofillers for Aerospace Applications, 2022: p. 55.
    Search in Google ScholarBack to article
  14. Quan, D., et al., On the application of strong thermoplastic–thermoset interactions for developing advanced aerospace-composite joints. Thin-Walled Structures, 2023. 186: p. 110671.
    Search in Google ScholarBack to article
  15. Kausar, A., Future and challenging attributes of aeronautical nanocomposites. Polymeric Nanocomposites with Carbonaceous Nanofillers for Aerospace Applications, 2022: p. 317.
    Search in Google ScholarBack to article
  16. Gaiotti, M. and C.M. Rizzo, Buckling behavior of FRP sandwich panels made by hand layup and vacuum bag infusion procedure. Rizzuto & Guedes Soares (eds), Sustainable Maritime Transportation and Exploitation of Sea Resources, 2011: p. 385-392.
    Search in Google ScholarBack to article
  17. Atas, C., et al., An experimental investigation on the low velocity impact response of composite plates repaired by VARIM and hand lay-up processes. Composite Structures, 2011. 93(3): p. 1178-1186.
    Search in Google ScholarBack to article
  18. Firuz, Z., L.C. Shing, and S.A.S.N. Fadzli. Flexural Properties of Al/Floral Foam Sandwich Composite Prepared by Hand Lay Up Process. in IOP Conference Series: Materials Science and Engineering. 2019.
    Search in Google ScholarBack to article
  19. Chen, C., et al., Prediction of the resin fillet size in honeycomb sandwich composites with self-adhesive prepreg skin. Journal of Reinforced Plastics and Composites, 2016. 35(21): p. 1566-1575.
    Search in Google ScholarBack to article
  20. Chen, C., et al., Improvement in skin–core adhesion of multiwalled carbon nanotubes modified carbon fiber prepreg/Nomex honeycomb sandwich composites. Journal of Reinforced Plastics and Composites, 2017. 36(8): p. 608-618.
    Search in Google ScholarBack to article
  21. Uddin, M., et al., Adhesiveless honeycomb sandwich structures of prepreg carbon fiber composites for primary structural applications. Advanced Composites and Hybrid Materials, 2019. 2(2): p. 339-350.
    Search in Google ScholarBack to article
  22. Valenza, A. and V. Fiore, Influence of resin viscosity and vacuum level on mechanical performance of sandwich structures manufactured by vacuum bagging. Advances in Polymer Technology: Journal of the Polymer Processing Institute, 2010. 29(1): p. 20-30.
    Search in Google ScholarBack to article
  23. Kratz, J. and P. Hubert, Vacuum bag only co-bonding prepreg skins to aramid honeycomb core. Part I. Model and material properties for core pressure during processing. Composites Part A: Applied Science and Manufacturing, 2015. 72: p. 228-238.
    Search in Google ScholarBack to article
  24. Lavaggi, T., et al., Theory-guided machine learning for optimal autoclave co-curing of sandwich composite structures. Polymer Composites, 2022. 43(8): p. 5319-5331.
    Search in Google ScholarBack to article
  25. Rudd, C., Resin transfer molding and structural reaction injection molding. ASM Handbook, 2001. 21: p. 492-500.
    Search in Google ScholarBack to article
  26. Torres, J.P., et al., Manufacture of green-composite sandwich structures with basalt fiber and bioepoxy resin. Advances in Materials Science and Engineering, 2013. 2013.
    Search in Google ScholarBack to article
  27. Gall, M., G. Steinbichler, and R.W. Lang, Learnings about design from recycling by using post-consumer polypropylene as a core layer in a co-injection molded sandwich structure product. Materials & Design, 2021. 202: p. 109576.
    Search in Google ScholarBack to article
  28. Wakeman, M., et al., Compression moulding of glass and polypropylene composites for optimised macro-and micro-mechanical properties. 4: Technology demonstrator—a door cassette structure. Composites Science and Technology, 2000. 60(10): p. 1901-1918.
    Search in Google ScholarBack to article
  29. Åkermo, M. and B.T. Åström, Modelling component cost in compression moulding of thermoplastic composite and sandwich components. Composites Part A: Applied Science and Manufacturing, 2000. 31(4): p. 319-333.
    Search in Google ScholarBack to article
  30. Fette, M., et al. New approach for the efficient manufacturing of sandwich structures based on sheet moulding compounds. Advanced Materials Research, 2016. 1140: p. 264-271.
    Search in Google ScholarBack to article
  31. Zhang, J., et al., Effect of natural fibre reinforcement on the sound and vibration damping properties of bio-composites compression moulded by nonwoven mats. Composites Communications, 2019. 13: p. 12-17.
    Search in Google ScholarBack to article
  32. Bonthu, D., et al., 3D printing of syntactic foam cored sandwich composite. Composites Part C: Open Access, 2020. 3: p. 100068.
    Search in Google ScholarBack to article
  33. Bharath, H., et al., Flexural response of 3D printed sandwich composite. Composite Structures, 2021. 263: p. 113732.
    Search in Google ScholarBack to article
  34. Essassi, K., et al., Experimental and analytical investigation of the bending behaviour of 3D-printed bio-based sandwich structures composites with auxetic core under cyclic fatigue tests. Composites Part A: Applied Science and Manufacturing, 2020. 131: p. 105775.
    Search in Google ScholarBack to article
  35. Kumar, S.K., et al., 50th anniversary perspective: are polymer nanocomposites practical for applications? Macromolecules, 2017. 50(3): p. 714-731.
    Search in Google ScholarBack to article
  36. Zaghloul, M.M.Y., M.M.Y. Zaghloul, and M. Fuseini, Recent progress in Epoxy Nanocomposites: Corrosion, structural, flame retardancy and applications—A comprehensive review. Polymers for Advanced Technologies, 2023.
    Search in Google ScholarBack to article
  37. Xie, X.-L., Y.-W. Mai, and X.-P. Zhou, Dispersion and alignment of carbon nanotubes in polymer matrix: a review. Materials Science and Engineering: R: Reports, 2005. 49(4): p. 89-112.
    Search in Google ScholarBack to article
  38. Ma, P.-C., et al., Dispersion and functionalization of carbon nanotubes for polymer-based nanocomposites: a review. Composites Part A: Applied Science and Manufacturing, 2010. 41(10): p. 1345-1367.
    Search in Google ScholarBack to article
  39. Roy, S., et al., Facile fabrication of superior nanofiltration membranes from interfacially polymerized CNT-polymer composites. Journal of Membrane Science, 2011. 375(1-2): p. 81-87.
    Search in Google ScholarBack to article
  40. Punetha, V.D., et al., Functionalization of carbon nanomaterials for advanced polymer nanocomposites: A comparison study between CNT and graphene. Progress in Polymer Science, 2017. 67: p. 1-47.
    Search in Google ScholarBack to article
  41. Kumari, S., et al. Advanced Welding of Dissimilar Materials for Aerospace and Automotive Applications. in E3S Web of Conferences. 2023.
    Search in Google ScholarBack to article
  42. Bharatiya, D., et al., A materials science approach towards bioinspired polymeric nanocomposites: a comprehensive review. International Journal of Polymeric Materials and Polymeric Biomaterials, 2023. 72(2): p. 119-134.
    Search in Google ScholarBack to article
  43. Yang, H., et al., Effect of nanofiller shape on viscoelasticity of rubber nanocomposite investigated by FEA. Composites Part B: Engineering, 2016. 92: p. 160-166.
    Search in Google ScholarBack to article
  44. Saxena, A., et al., A short review on machine learning for the purpose of optimizing and predicting the properties of polymeric nanocomposites. Materials Today: Proceedings, 2023.
    Search in Google ScholarBack to article
  45. Netravali, A.N. and K. Mittal, Interface/interphase in polymer nanocomposites. 2016: John Wiley & Sons.
    Search in Google ScholarBack to article
  46. Barik, S.B., et al., Recent progress in reinforcement of nanofillers in epoxy-based nanocomposites. Materials Today: Proceedings, 2023.
    Search in Google ScholarBack to article
  47. Ranjan, P., et al., Theoretical analysis: electronic and optical properties of small Cu-Ag nano alloy clusters. Computational Chemistry Methodology in Structural Biology and Materials Sciences, 2017.
    Search in Google ScholarBack to article
  48. Kim, K., et al., Polyphenylene sulfide/liquid crystal polymer blend system for laser direct structuring and electroless plating applications. Composites Part B: Engineering, 2019. 166: p. 742-748.
    Search in Google ScholarBack to article
  49. Belkheir, M., et al., Effect of carbon nanotube (CNT)-reinforced polymers and biopolymer matrix on interface damage of nanocomposite materials. Emergent Materials, 2023: p. 1-14.
    Search in Google ScholarBack to article
  50. Rudyak, V.Y., et al., Comparative characteristics of viscosity and rheology of nanofluids with multi-walled and single-walled carbon nanotubes. Diamond and Related Materials, 2023. 132: p. 109616.
    Search in Google ScholarBack to article
  51. Ou, Y., L. Wu, and D. Mao, Hierarchical mode I interlaminar toughening of unidirectional CFRP laminates by the synergistic effects of CNT powders and veils. Composites Part A: Applied Science and Manufacturing, 2023. 168: p. 107464.
    Search in Google ScholarBack to article
  52. Sui, G., et al., The dispersion of CNT in TPU matrix with different preparation methods: solution mixing vs melt mixing. Polymer, 2019. 182: p. 121838.
    Search in Google ScholarBack to article
  53. Gu, X., et al., The meniscus-guided deposition of semiconducting polymers. Nature Communications, 2018. 9(1): p. 1-16.
    Search in Google ScholarBack to article
  54. Vorobei, A.M., et al., Preparation of polymer–multi-walled carbon nanotube composites with enhanced mechanical properties using supercritical antisolvent precipitation. Polymer, 2016. 95: p. 77-81.
    Search in Google ScholarBack to article
  55. Saeed, K., et al., Graphene and carbon nanotubes-based polymer nanocomposites. Smart Polymer Nanocomposites. 2023, Elsevier. p. 205-218.
    Search in Google ScholarBack to article
  56. Fawaz, J. and V. Mittal, Synthesis of polymer nanocomposites: review of various techniques. 2015, Wiley Online Library. p. 992-1057.
    Search in Google ScholarBack to article
  57. Gong, H., et al., Precise Synthesis of Ultra-High-Molecular-Weight Fluoropolymers Enabled by Chain-Transfer-Agent Differentiation under Visible-Light Irradiation. Angewandte Chemie International Edition, 2020. 59(2): p. 919-927.
    Search in Google ScholarBack to article
  58. Kausar, A., Self-healing polymer/carbon nanotube nanocomposite: A review. Journal of Plastic Film & Sheeting, 2021. 37(2): p. 160-181.
    Search in Google ScholarBack to article
  59. Chen, X., et al., Improving the flame retardancy and mechanical properties of epoxy composites significantly with a low-loading CNT-based hierarchical hybrid decorated with reactive hyperbranched polyphosphoramide. Applied Surface Science, 2022. 576: p. 151765.
    Search in Google ScholarBack to article
  60. Chazot, C.A., et al., Molecular alignment of a meta-aramid on carbon nanotubes by in situ interfacial polymerization. Nano Letters, 2022. 22(3): p. 998-1006.
    Search in Google ScholarBack to article
  61. Lopes Pereira, E.C. and B.G. Soares, Conducting epoxy networks modified with non-covalently functionalized multi-walled carbon nanotube with imidazolium-based ionic liquid. Journal of Applied Polymer Science, 2016. 133(38).
    Search in Google ScholarBack to article
  62. Soman, V., K. Vishwakarma, and M.K. Poddar, Ultrasound assisted synthesis of polymer nanocomposites: a review. Journal of Polymer Research, 2023. 30(11): p. 406.
    Search in Google ScholarBack to article
  63. Sharma, D., et al., Bio-based polyamide nanocomposites of nanoclay, carbon nanotubes and graphene: a review. Iranian Polymer Journal, 2023. 32(6): p. 773-790.
    Search in Google ScholarBack to article
  64. Abral, H., et al., A simple method for improving the properties of the sago starch films prepared by using ultrasonication treatment. Food Hydrocolloids, 2019. 93: p. 276-283.
    Search in Google ScholarBack to article
  65. Fu, X., et al., Molecular modeling investigation on mechanism of diazinon pesticide removal from water by single-and multi-walled carbon nanotubes. Ecotoxicology and Environmental Safety, 2023. 256: p. 114857.
    Search in Google ScholarBack to article
  66. Uyor, U.O., et al., A review of recent advances on the properties of polypropylene-carbon nanotubes composites. Journal of Thermoplastic Composite Materials, 2023. 36(9): p. 3737-3770.
    Search in Google ScholarBack to article
  67. Dolbin, I., G.M. Magomedov, and G. Kozlov, Effect of Polymer Matrix Stiffness on Carbon Nanotube-Reinforced Polymer Composites. Russian Physics Journal, 2023. 65(12): p. 2182-2185.
    Search in Google ScholarBack to article
  68. Krause, B., et al., Influence of Polyvinylpyrrolidone on Thermoelectric Properties of Melt-Mixed Polymer/Carbon Nanotube Composites. Micromachines, 2023. 14(1): p. 181.
    Search in Google ScholarBack to article
  69. Soni, S.K., et al., Carbon nanotubes as exceptional nanofillers in polymer and polymer/fiber nanocomposites: An extensive review. Materials Today Communications, 2023: p. 107358.
    Search in Google ScholarBack to article
  70. Kaplan, M., et al., Bicomponent melt spinning of polyamide 6/carbon nanotube/carbon black filaments: Investigation of effect of melt mass-flow rate on electrical conductivity. Journal of Industrial Textiles, 2023. 53: p. 15280837231186174.
    Search in Google ScholarBack to article
  71. Alshahrani, H., et al., Mechanical properties study on sandwich composites of glass fiber reinforced plastics (GFRP) using liquid thermoplastic resin, Elium®: preliminary experiments. Coatings, 2022. 12(10): p. 1423.
    Search in Google ScholarBack to article
  72. Chen, Q., et al., Mechanical properties in glass fiber PVC-foam sandwich structures from different chopped fiber interfacial reinforcement through vacuum-assisted resin transfer molding (VARTM) processing. Composites Science and Technology, 2017. 144: p. 202-207.
    Search in Google ScholarBack to article
  73. Li, Z., et al., Manufacturing and mechanical characterisation of polyurethane resin based sandwich composites for three-dimensional fabric reinforcement. Materials Today Communications, 2020. 24: p. 101046.
    Search in Google ScholarBack to article
  74. Garrido, M., et al., Multi-objective optimization of pultruded composite sandwich panels for building floor rehabilitation. Construction and Building Materials, 2019. 198: p. 465-478.
    Search in Google ScholarBack to article
  75. Dikshit, V., et al. Investigation of out of plane compressive strength of 3D printed sandwich composites. IOP Conference Series: Materials Science and Engineering. 2016.
    Search in Google ScholarBack to article
  76. Li, T. and L. Wang, Bending behavior of sandwich composite structures with tunable 3D-printed core materials. Composite Structures, 2017. 175: p. 46-57.
    Search in Google ScholarBack to article
  77. Jakubinek, M.B., et al., Single-walled carbon nanotube–epoxy composites for structural and conductive aerospace adhesives. Composites Part B: Engineering, 2015. 69: p. 87-93.
    Search in Google ScholarBack to article
  78. Wang, Y., et al., Sustainable self-healing at ultra-low temperatures in structural composites incorporating hollow vessels and heating elements. Royal Society Open Science, 2016. 3(9): p. 160488.
    Search in Google ScholarBack to article
  79. Wang, D. and S. Li, Collaborative optimization design of lightweight and crashworthiness of the front-end structures of automobile body using HW–GRA for Pareto mining. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2021: p. 0954406221992802.
    Search in Google ScholarBack to article
  80. Ikumapayi, O.M. and E.T. Akinlabi, Efficacy of α-β grade titanium alloy powder (Ti–6Al– 2Sn–2Zr–2Mo–2Cr–0.25 Si) in surface modification and corrosion mitigation in 3.5% NaCl on friction stir processed armour grade 7075-T651 aluminum alloys—insight in defence applications. Materials Research Express, 2019. 6(7): p. 076546.
    Search in Google ScholarBack to article
  81. Guadagno, L., et al., Functional structural nanocomposites with integrated self-healing ability. Materials Today: Proceedings, 2021. 34: p. 243-249.
    Search in Google ScholarBack to article
  82. Chowdhury, N.M., et al., Static and fatigue testing bolted, bonded and hybrid step lap joints of thick carbon fibre/epoxy laminates used on aircraft structures. Composite Structures, 2016. 142: p. 96-106.
    Search in Google ScholarBack to article
  83. Nayak, S.Y., et al., Mechanical properties of multi layer plain weave and 3-D glass fabric epoxy composites. International Journal of Composite Materials, 2015. 5(2): p. 30-36.
    Search in Google ScholarBack to article
  84. Vieira, D.R., R.K. Vieira, and M. Chang Chain, Strategy and management for the recycling of carbon fiber-reinforced polymers (CFRPs) in the aircraft industry: a critical review. International Journal of Sustainable Development & World Ecology, 2017. 24(3): p. 214-223.
    Search in Google ScholarBack to article
  85. Mrazova, M., Advanced composite materials of the future in aerospace industry. Incas Bulletin, 2013. 5(3): p. 139.
    Search in Google ScholarBack to article
  86. Abliz, D., et al., Curing methods for advanced polymer composites-a review. Polymers and Polymer Composites, 2013. 21(6): p. 341-348.
    Search in Google ScholarBack to article
  87. Li, C. and A. Strachan, Evolution of network topology of bifunctional epoxy thermosets during cure and its relationship to thermo-mechanical properties: A molecular dynamics study. Polymer, 2015. 75: p. 151-160.
    Search in Google ScholarBack to article
  88. Öztürkmen, M.B., Y. Öz, and N. Dilsiz, Physical and mechanical properties of graphene and h-Boron nitride reinforced hybrid aerospace grade epoxy nanocomposites. Journal of Applied Polymer Science, 2023: p. e54639.
    Search in Google ScholarBack to article
  89. Chen, H., et al., Mechanical properties of reactive polyetherimide-modified tetrafunctional epoxy systems. Polymer, 2023. 270: p. 125763.
    Search in Google ScholarBack to article
  90. Tambe, P., M. Tanniru, and B.K. Sai, Structural/load bearing characteristics of polymer-graphene composites, in Polymer Nanocomposites Containing Graphene. 2022. p. 379-400.
    Search in Google ScholarBack to article
  91. Torrisi, L., et al., Graphene oxide modifications by X-rays irradiations in air and vacuum. Vacuum, 2023: p. 112283.
    Search in Google ScholarBack to article
  92. Ferreira, F., et al., Functionalized graphene oxide as reinforcement in epoxy based nanocomposites. Surfaces and Interfaces, 2018. 10: p. 100-109.
    Search in Google ScholarBack to article
  93. Bortz, D.R., E.G. Heras, and I. Martin-Gullon, Impressive fatigue life and fracture toughness improvements in graphene oxide/epoxy composites. Macromolecules, 2012. 45(1): p. 238-245.
    Search in Google ScholarBack to article
  94. Cao, G., et al., Resilient graphene ultrathin flat lens in aerospace, chemical, and biological harsh environments. ACS Applied Materials & Interfaces, 2019. 11(22): p. 20298-20303.
    Search in Google ScholarBack to article
  95. Naseer, Z. and Z. Khan. Graphene Effect on Mechanical Properties of Sandwich Panel for Aerospace Structures. Key Engineering Materials. 2021.
    Search in Google ScholarBack to article
  96. Sahu, M. and A.M. Raichur, Toughening of high performance tetrafunctional epoxy with poly (allyl amine) grafted graphene oxide. Composites Part B: Engineering, 2019. 168: p. 15-24.
    Search in Google ScholarBack to article
  97. Kausar, A., Review on conducting polymer/nanodiamond nanocomposites: Essences and functional performance. Journal of Plastic Film & Sheeting, 2019. 35(4): p. 331-353.
    Search in Google ScholarBack to article
  98. Krueger, A. and D. Lang, Functionality is key: recent progress in the surface modification of nanodiamond. Advanced Functional Materials, 2012. 22(5): p. 890-906.
    Search in Google ScholarBack to article
  99. Zulkefli, N.A., et al., Hybrid nanofiller reinforcement in thermoset and biothermoset applications: A review. Nanotechnology Reviews, 2023. 12(1): p. 20220499.
    Search in Google ScholarBack to article
  100. Wirth, D.M. and J.K. Pokorski, Design and fabrication of a low-cost pilot-scale melt-processing system. Polymer, 2019. 181: p. 121802.
    Search in Google ScholarBack to article
  101. Singh, B. and A. Mohanty, Nano-mechanical approach to study the behavior of annealed nanodiamond reinforced epoxy nanocomposites. Polymer Composites, 2023. 44(5): p. 2997-3006.
    Search in Google ScholarBack to article
  102. Shuai, C., et al., Surface modification of nanodiamond: toward the dispersion of reinforced phase in poly-l-lactic acid scaffolds. International Journal of Biological Macromolecules, 2019. 126: p. 1116-1124.
    Search in Google ScholarBack to article
  103. Zhang, Y., J.R. Choi, and S.-J. Park, Thermal conductivity and thermo-physical properties of nanodiamond-attached exfoliated hexagonal boron nitride/epoxy nanocomposites for microelectronics. Composites Part A: Applied Science and Manufacturing, 2017. 101: p. 227-236.
    Search in Google ScholarBack to article
  104. Xie, K., et al., High-strength Al Matrix Composites Reinforced With Uniformly Dispersed Nanodiamonds. Journal of Alloys and Compounds, 2021: p. 162917.
    Search in Google ScholarBack to article
  105. Zhao, J., et al., Electrospinning Technique Meets Solar Energy: Electrospun Nanofiber-Based Evaporation Systems for Solar Steam Generation. Advanced Fiber Materials, 2023: p. 1-31.
    Search in Google ScholarBack to article
  106. Arora, M., et al., Dielectric and Magneto-dielectric properties of GdFeO3 modified PbTiO3 nanofibrous mats obtained through electrospinning technique. Materials Science and Engineering: B, 2023. 296: p. 116702.
    Search in Google ScholarBack to article
  107. Liu, L., et al., Preparation of high-performance graphene materials by adjusting internal micro-channels using a combined electrospray/electrospinning technique. Journal of Alloys and Compounds, 2023. 940: p. 168882.
    Search in Google ScholarBack to article
  108. Kausar, A., Nanodiamond/mwcnt-based polymeric nanofiber reinforced poly (bisphenol a-coepichlorohydrin). Malays Polymer Journal, 2015. 10: p. 23-32.
    Search in Google ScholarBack to article
  109. Wang, H., et al., The influence of the ultrasonic treatment of working fluids on electrospun amorphous solid dispersions. Frontiers in Molecular Biosciences, 2023. 10: p. 1184767.
    Search in Google ScholarBack to article
  110. Yoshitomi, T., T. Matsumoto, and T. Nishino, Highly Thermally Conductive Nanocomposites Prepared by the Ice-Templating Alignment of Nanodiamonds in the Thickness Direction. ACS Applied Polymer Materials, 2023.
    Search in Google ScholarBack to article
  111. Behler, K.D., et al., Nanodiamond-polymer composite fibers and coatings. ACS Nano, 2009. 3(2): p. 363-369.
    Search in Google ScholarBack to article
  112. Sun, C., et al., Preparation and their thermal properties of the nanodiamond/polyacrylonitrile composite nanofibers generated from electrospinning. Journal of Polymer Research, 2019. 26(6): p. 1-7.
    Search in Google ScholarBack to article
  113. Rianjanu, A., et al., Quartz crystal microbalance humidity sensors integrated with hydrophilic polyethyleneimine-grafted polyacrylonitrile nanofibers. Sensors and Actuators B: Chemical, 2020. 319: p. 128286.
    Search in Google ScholarBack to article
  114. Adegbola, T., O. Agboola, and O. Fayomi, Review of polyacrylonitrile blends and application in manufacturing technology: recycling and environmental impact. Results in Engineering, 2020. 7: p. 100144.
    Search in Google ScholarBack to article
  115. Alishiri, M. and A. Shojaei, In situ preparation and characterization of biocompatible acrylate-terminated polyurethane containing chemically modified multiwalled carbon nanotube. Polymer Composites, 2018. 39: p. E297-E307.
    Search in Google ScholarBack to article
  116. Alishahi, E., et al., Effects of carbon nanoreinforcements of different shapes on the mechanical properties of epoxy-based nanocomposites. Macromolecular Materials and Engineering, 2013. 298(6): p. 670-678.
    Search in Google ScholarBack to article
  117. Latif, Z., et al., Thermal and Mechanical Properties of Nano-Carbon-Reinforced Polymeric Nanocomposites: A Review. Journal of Composites Science, 2023. 7(10): p. 441.
    Search in Google ScholarBack to article
  118. Morimune, S., et al., Poly (vinyl alcohol) nanocomposites with nanodiamond. Macromolecules, 2011. 44(11): p. 4415-4421.
    Search in Google ScholarBack to article
  119. Kausar, A., Advances in condensation polymer containing zero-dimensional nanocarbon reinforcement—fullerene, carbon nano-onion, and nanodiamond. Polymer-Plastics Technology and Materials, 2021. 60(7): p. 695-713.
    Search in Google ScholarBack to article
  120. Kausar, A., Conducting Polymer-Based Nanocomposites: Fundamentals and Applications. 2021: Elsevier.
    Search in Google ScholarBack to article
  121. Singh, P.P., Advances in Carbon Nanomaterial-Based Green Nanocomposites. Emerging Carbon-Based Nanocomposites for Environmental Applications, 2020: p. 175-201.
    Search in Google ScholarBack to article
  122. Li, Y., et al., A review of the electrical and mechanical properties of carbon nanofiller-reinforced polymer composites. Journal of Materials Science, 2019. 54(2): p. 1036-1076.
    Search in Google ScholarBack to article
  123. Kim, J.B., T.W. Kim, and C.G. Kim, Simulation method for complex permittivities of carbon black/epoxy composites at microwave frequency band. Journal of Applied Polymer Science, 2006. 100(3): p. 2189-2195.
    Search in Google ScholarBack to article
  124. Verma, A., et al., Mechanical, microstructural, and thermal characterization insights of pyrolyzed carbon black from waste tires reinforced epoxy nanocomposites for coating application. Polymer Composites, 2020. 41(1): p. 338-349.
    Search in Google ScholarBack to article
  125. Roopa, T., et al., Mechanical properties of vinylester/glass and polyester/glass composites fabricated by resin transfer molding and hand lay-up. Journal of Vinyl and Additive Technology, 2015. 21(3): p. 166-173.
    Search in Google ScholarBack to article
  126. Beyerlein, I.J. and S.L. Phoenix, Statistics for the strength and size effects of microcomposites with four carbon fibers in epoxy resin. Composites Science and Technology, 1996. 56(1): p. 75-92.
    Search in Google ScholarBack to article
  127. Li, S., et al., Advances in hybrid fibers reinforced polymer-based composites prepared by FDM: A review on mechanical properties and prospects. Composites Communications, 2023: p. 101592.
    Search in Google ScholarBack to article
  128. Balaji, K., K. Shirvanimoghaddam, and M. Naebe, Multifunctional basalt fiber polymer composites enabled by carbon nanotubes and graphene. Composites Part B: Engineering, 2023: p. 111070.
    Search in Google ScholarBack to article
  129. Dong, J., et al., Improved mechanical properties of carbon fiber-reinforced epoxy composites by growing carbon black on carbon fiber surface. Composites Science and Technology, 2017. 149: p. 75-80.
    Search in Google ScholarBack to article
  130. Kausar, A., Fullerene nanofiller reinforced epoxy nanocomposites—Developments, progress and challenges. Materials Research Innovations, 2021. 25(3): p. 175-185.
    Search in Google ScholarBack to article
  131. Kausar, A. and R. Taherian, 3-Electrical Conductivity Behavior of Polymer Nanocomposite with Carbon Nanofillers. Electrical Conductivity in Polymer-Based Composites Experiments, Modelling, and Applications; Plastics Design Library, 2018: p. 41-72.
    Search in Google ScholarBack to article
  132. Kong, X., et al. Dielectric properties of epoxy-based nanocomposite filled with fullerene C60. in 2020 IEEE 3rd International Conference on Dielectrics (ICD). 2020. IEEE.
    Search in Google ScholarBack to article
  133. Kausar, A., Advances in Polymeric Nanocomposites Incorporating Graphene–Fullerene and Graphene Oxide–Fullerene Hybrids, in All-carbon Composites and Hybrids. 2021, Royal Society of Chemistry. p. 255-277.
    Search in Google ScholarBack to article
  134. Kausar, A., Poly (methyl methacrylate)/Fullerene nanocomposite—Factors and applications. Polymer-Plastics Technology and Materials, 2021: p. 1-16.
    Search in Google ScholarBack to article
  135. Kausar, A., Potential of polymer/fullerene nanocomposites for anticorrosion applications in the biomedical field. Journal of Composites Science, 2022. 6(12): p. 394.
    Search in Google ScholarBack to article
  136. Kausar, A., Cutting-edge Shape Memory Polymer/Fullerene Nanocomposite: Design and Contemporary Status. Polymer-Plastics Technology and Materials, 2023. 62(5): p. 604-617.
    Search in Google ScholarBack to article
  137. Rafiee, M.A., et al., Fullerene–epoxy nanocomposites-enhanced mechanical properties at low nanofiller loading. Journal of Nanoparticle Research, 2011. 13(2): p. 733-737.
    Search in Google ScholarBack to article
  138. Dai, Y., et al., Characterization of tensile failure behaviour of magnesia refractory materials by a modified dog-bone shape direct tensile method and splitting tests. Ceramics International, 2020. 46(5): p. 6517-6525.
    Search in Google ScholarBack to article
  139. Zhang, Y.-F., et al., A novel approach for the edge rolling force and dog-bone shape by combination of slip-line and exponent velocity field. SN Applied Sciences, 2020. 2(12): p. 1-11.
    Search in Google ScholarBack to article
  140. Kim, J.-H., et al., Mechanical properties of polymer–fullerene bulk heterojunction films: Role of nanomorphology of composite films. Chemistry of Materials, 2017. 29(9): p. 3954-3961.
    Search in Google ScholarBack to article
  141. Giannopoulos, G.I., Linking MD and FEM to predict the mechanical behaviour of fullerene reinforced nylon-12. Composites Part B: Engineering, 2019. 161: p. 455-463.
    Search in Google ScholarBack to article
  142. Zuev, V. Polymer nanocomposites containing fullerene C60 nanofillers. in Macromolecular Symposia. 2011. Wiley Online Library.
    Search in Google ScholarBack to article
  143. Khan, W., R. Sharma, and P. Saini, Carbon nanotube-based polymer composites: synthesis, properties and applications. Carbon Nanotubes-Current Progress of their Polymer Composites, 2016.
    Search in Google ScholarBack to article
  144. Mamidi, N., et al., Carbonaceous nanomaterials incorporated biomaterials: The present and future of the flourishing field. Composites Part B: Engineering, 2022: p. 110150.
    Search in Google ScholarBack to article
  145. Anwer, A.H., et al., State-of-the-art advances in nanocomposite and bio-nanocomposite polymeric materials: A comprehensive review. Advances in Colloid and Interface Science, 2023: p. 102955.
    Search in Google ScholarBack to article
  146. Mousavi, S.R., et al., A review of recent progress in improving the fracture toughness of epoxy-based composites using carbonaceous nanofillers. Polymer Composites, 2022. 43(4): p. 1871-1886.
    Search in Google ScholarBack to article
  147. Kausar, A., Corrosion prevention prospects of polymeric nanocomposites: A review. Journal of Plastic Film & Sheeting, 2019. 35(2): p. 181-202.
    Search in Google ScholarBack to article
  148. D'Antino, T., et al., Tensile and interlaminar shear behavior of thermoset and thermoplastic GFRP bars exposed to alkaline environment. Journal of Building Engineering, 2023. 72: p. 106581.
    Search in Google ScholarBack to article
  149. Khanjar, S., et al., Mixed Matrix Thermoset Casting with Thermoplastic Fused Filament Fabrication 3D Printing. Physiology, 2023. 38(S1): p. 5733152.
    Search in Google ScholarBack to article
  150. Ding, C., et al., A review of 1D carbon-based materials assembly design for lightweight microwave absorption. Carbon, 2023: p. 118279.
    Search in Google ScholarBack to article
  151. Liu, H., et al., Modification of MWNTs by the combination of Li-TFSI and MAPP: Novel strategy to high performance PP/MWNTs nanocomposites. Composites Part B: Engineering, 2019. 176: p. 107268.
    Search in Google ScholarBack to article
  152. Mondal, S., et al., Thermal-air ageing treatment on mechanical, electrical, and electromagnetic interference shielding properties of lightweight carbon nanotube based polymer nanocomposites. Composites Part A: Applied Science and Manufacturing, 2018. 107: p. 447-460.
    Search in Google ScholarBack to article
  153. Jayalakshmy, M. and R.K. Mishra, Applications of Carbon-Based Nanofiller-Incorporated Rubber Composites in the Fields of Tire Engineering, Flexible Electronics and EMI Shielding, in Carbon-Based Nanofiller and Their Rubber Nanocomposites. 2019, Elsevier. p. 441-472.
    Search in Google ScholarBack to article
  154. Zhang, X., et al., Design of glass fiber reinforced plastics modified with CNT and pre-stretching fabric for potential sports instruments. Materials & Design, 2016. 92: p. 621-631.
    Search in Google ScholarBack to article
  155. Miao, T., Y. Ding, and Z. Zhai, Overmolded hybrid thermoset-thermoplastic structures: Experimental study on the bonding strength of co-curing thermoplastic film onto thermoset composite. Journal of Applied Polymer Science, 2023. 140(7): p. e53488.
    Search in Google ScholarBack to article
  156. Cao, X., et al., Screen printing as a scalable and low-cost approach for rigid and flexible thin-film transistors using separated carbon nanotubes. ACS Nano, 2014. 8(12): p. 12769-12776.
    Search in Google ScholarBack to article
  157. Li, Y., et al., High-efficiency robust perovskite solar cells on ultrathin flexible substrates. Nature Communications, 2016. 7(1): p. 1-10.
    Search in Google ScholarBack to article
  158. Rathore, D. and U.K. Dwivedi, 2 Advanced Nanocarbon Materials. Advanced Nanocarbon Materials: Applications for Health Care, 2022: p. 11.
    Search in Google ScholarBack to article
  159. Toozandehjani, M., et al., Conventional and advanced composites in aerospace industry: technologies revisited. American Journal of Aerospace Engineering 2018. 5: p. 9-15.
    Search in Google ScholarBack to article
  160. Li, C., et al., Microstructure and strengthening mechanism of carbon nanotubes reinforced magnesium matrix composite. Materials Science and Engineering: A, 2014. 597: p. 264-269.
    Search in Google ScholarBack to article
DOI: https://doi.org/10.2478/adms-2023-0025 | Journal eISSN: 2083-4799 | Journal ISSN: 1730-2439
Journal RSS Feed
Language: English
Page range: 99 - 122
Submitted on: Oct 11, 2023
|
Accepted on: Dec 1, 2023
|
Published on: Dec 20, 2023
Published by: Gdansk University of Technology
In partnership with: Paradigm Publishing Services
Publication frequency: 4 issues per year
Keywords:
carbonaceous,
nanofiller,
polymer,
nanocomposite,
aerospace,
strength
Related subjects:
Materials sciences,
Functional and smart materials

© 2023 Ayesha Kausar, Ishaq Ahmad, published by Gdansk University of Technology
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.

Previous articleVolume 23 (2023): Issue 4 (December 2023)Next article