This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Robert, U.W., et al., Electrical characteristics of dry cement–based composites modified with coconut husk ash nanomaterial. Advances in Materials Science, 2022. 22(2): p. 64-77.Search in Google Scholar
Hoque, M.A., et al., Recycling waste polypropylene to produce new composite materials with jute reinforcements. Advances in Materials Science, 2023. 23(3): p. 21-32.Search in Google Scholar
Kausar, A., Advances in carbon fiber reinforced polyamide-based composite materials. Advances in materials science, 2019. 19(4): p. 67-82.Search in Google Scholar
Czupryński, A. and C. Mele, Properties of flame spraying coatings reinforced with particles of carbon nanotubes. Advances in Materials Science, 2021. 21(1): p. 57-76.Search in Google Scholar
Kausar, A., Review of fundamentals and applications of polyester nanocomposites filled with carbonaceous nanofillers. Journal of Plastic Film & Sheeting, 2019. 35(1): p. 22-44.Search in Google Scholar
Ciecieląg, K., K. Kęcik, and K. Zaleski, Effect of depth surface defects in carbon fibre reinforced composite material on the selected recurrence quantifications. Advances in Materials Science, 2020. 20(2): p. 71-80.Search in Google Scholar
Savilov, S.V., et al., Temperature dependences of paramagnetic response in oxidized spark plasma sintered carbon nanotubes: The way of understanding the local electronic structure. Solid State Sciences, 2022. 132: p. 106996.Search in Google Scholar
Liu, H., et al., Direct ink writing of chopped carbon fibers reinforced polymer-derived SiC composites with low shrinkage and high strength. Journal of the European Ceramic Society, 2023. 43(2): p. 235-244.Search in Google Scholar
Dai, Z., et al., Effect of sizing on carbon fiber surface properties and fibers/epoxy interfacial adhesion. Applied Surface Science, 2011. 257(15): p. 6980-6985.Search in Google Scholar
Sha, J.-j., et al., Improved wettability and mechanical properties of metal coated carbon fiber-reinforced aluminum matrix composites by squeeze melt infiltration technique. Transactions of Nonferrous Metals Society of China, 2021. 31(2): p. 317-330.Search in Google Scholar
Oladele, I.O., T.F. Omotosho, and A.A. Adediran, Polymer-based composites: an indispensable material for present and future applications. International Journal of Polymer Science, 2020. 2020: p. 1-12.Search in Google Scholar
Kroisová, D., et al., Destruction of Carbon and Glass Fibers during Chip Machining of Composite Systems. Polymers, 2023. 15(13): p. 2888.Search in Google Scholar
Yang, D., et al., Preparation, modification, and coating for carbon-bonded carbon fiber composites: a review. Ceramics International, 2022. 48(11): p. 14935-14958.Search in Google Scholar
Burkov, M.V. and A.V. Eremin, Mechanical properties of carbon‐fiber‐reinforced epoxy composites modified by carbon micro‐and nanofillers. Polymer Composites, 2021. 42(9): p. 4265-4276.Search in Google Scholar
Gopinath, A. and K. Kadirvelu, Strategies to design modified activated carbon fibers for the decontamination of water and air. Environmental Chemistry Letters, 2018. 16: p. 1137-1168.Search in Google Scholar
Wang, S., et al., Lignin-based carbon fibers: Formation, modification and potential applications. Green Energy & Environment, 2022. 7(4): p. 578-605.Search in Google Scholar
Röper, F., et al., Bonded aerospace repairs under tensile loading: Wet chemical surface treatment and selected environmental conditions. Journal of Applied Polymer Science, 2019. 136(19): p. 47506.Search in Google Scholar
Aussawasathien, D. and K. Hrimchum, Carboxylic-plasma-treated nanofiller hybrids in carbon fiber reinforced epoxy composites: Dispersion and synergetic effects. Express Polymer Letters, 2021. 15(3): p. 262-273.Search in Google Scholar
Chung, D., A review to elucidate the multi-faceted science of the electrical-resistance-based strain/temperature/damage self-sensing in continuous carbon fiber polymer-matrix structural composites. Journal of Materials Science, 2023. 58(2): p. 483-526.Search in Google Scholar
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 Scholar
Karataş, M.A. and H. Gökkaya, A review on machinability of carbon fiber reinforced polymer (CFRP) and glass fiber reinforced polymer (GFRP) composite materials. Defence Technology, 2018. 14(4): p. 318-326.Search in Google Scholar
Tan, X., et al., Metallic powder-bed based 3D printing of cellular scaffolds for orthopaedic implants: A state-of-the-art review on manufacturing, topological design, mechanical properties and biocompatibility. Materials Science and Engineering: C, 2017. 76: p. 1328-1343.Search in Google Scholar
Motyka, M., Titanium alloys and titanium-based matrix composites. 2021, MDPI. p. 1463.Search in Google Scholar
Boyer, R., et al., Materials considerations for aerospace applications. MRS Bulletin, 2015. 40(12): p. 1055-1066.Search in Google Scholar
Plocher, J. and A. Panesar, Review on design and structural optimisation in additive manufacturing: Towards next-generation lightweight structures. Materials & Design, 2019. 183: p. 108164.Search in Google Scholar
Thamizh Selvan, R., et al., Recycling technology of epoxy glass fiber and epoxy carbon fiber composites used in aerospace vehicles. Journal of Composite Materials, 2021: p. 00219983211011532.Search in Google Scholar
Xu, Z., et al., Recyclable thermoset hyperbranched polymers containing reversible hexahydro-striazine. Nature Sustainability, 2020. 3(1): p. 29-34.Search in Google Scholar
Yuan, D., et al., Recyclable conductive epoxy composites with segregated filler network structure for EMI shielding and strain sensing. Composites Part A: Applied Science and Manufacturing, 2020. 132: p. 105837.Search in Google Scholar
Wu, M.-S., et al., A recyclable epoxy for composite wind turbine blades. Advanced Manufacturing: Polymer & Composites Science, 2019. 5(3): p. 114-127.Search in Google Scholar
Wazalwar, R., M. Sahu, and A.M. Raichur, Mechanical properties of aerospace epoxy composites reinforced with 2D nano-fillers: current status and road to industrialization. Nanoscale Advances, 2021. 3(10): p. 2741-2776.Search in Google Scholar
Ramon, E., C. Sguazzo, and P.M. Moreira, A review of recent research on bio-based epoxy systems for engineering applications and potentialities in the aviation sector. Aerospace, 2018. 5(4): p. 110.Search in Google Scholar
Frigione, M. and M. Lettieri, Recent advances and trends of nanofilled/nanostructured epoxies. Materials, 2020. 13(15): p. 3415.Search in Google Scholar
Bachmann, J., C. Hidalgo, and S. Bricout, Environmental analysis of innovative sustainable composites with potential use in aviation sector—A life cycle assessment review. Science China Technological Sciences, 2017. 60: p. 1301-1317.Search in Google Scholar
Parandoush, P. and D. Lin, A review on additive manufacturing of polymer-fiber composites. Composite Structures, 2017. 182: p. 36-53.Search in Google Scholar
Chakraborty, S. and M.C. Biswas, 3D printing technology of polymer-fiber composites in textile and fashion industry: A potential roadmap of concept to consumer. Composite Structures, 2020. 248: p. 112562.Search in Google Scholar
Ma, X., et al., High-efficiently renewable hyperbranched epoxy resin/carbon fiber composites with both long service life and high performance. Composites Communications, 2023: p. 101630.Search in Google Scholar
Nabipour, H., et al., A bio-based intrinsically flame-retardant epoxy vitrimer from furan derivatives and its application in recyclable carbon fiber composites. Polymer Degradation and Stability, 2023. 207: p. 110206.Search in Google Scholar
Birniwa, A.H., et al., Recent Trends in Treatment and Fabrication of Plant-Based Fiber-Reinforced Epoxy Composite: A Review. Journal of Composites Science, 2023. 7(3): p. 120.Search in Google Scholar
Joliff, Y., et al., Study of the moisture/stress effects on glass fibre/epoxy composite and the impact of the interphase area. Composite Structures, 2014. 108: p. 876-885.Search in Google Scholar
Das, T.K., P. Ghosh, and N.C. Das, Preparation, development, outcomes, and application versatility of carbon fiber-based polymer composites: a review. Advanced Composites and Hybrid Materials, 2019: p. 1-20.Search in Google Scholar
Gezahegn, S., et al., Porous graphitic biocarbon and reclaimed carbon fiber derived environmentally benign lightweight composites. Science of The Total Environment, 2019. 664: p. 363-373.Search in Google Scholar
Öztürkmen, M.B., et al., Tailored multifunctional nanocomposites obtained by integration of carbonaceous fillers in an aerospace grade epoxy resin curing at high temperatures. Diamond and Related Materials, 2023. 135: p. 109840.Search in Google Scholar
Xavier, J.R. and S. Vinodhini, Investigation into the effect of introducing functionalized hafnium carbide with GO in the epoxy coated aluminium alloy for aerospace components. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2023. 658: p. 130667.Search in Google Scholar
Guadagno, L., et al., Development of epoxy mixtures for application in aeronautics and aerospace. Rsc Advances, 2014. 4(30): p. 15474-15488.Search in Google Scholar
Shabir, A., et al., Long-term prospects of nano-carbon and its derivatives as anode materials for lithium-ion batteries–A review. Journal of Energy Storage, 2023. 72: p. 108178.Search in Google Scholar
Kausar, A., Polymeric nanocomposite with polyhedral oligomeric silsesquioxane and nanocarbon (fullerene, graphene, carbon nanotube, nanodiamond)—Futuristic headways. Polymer-Plastics Technology and Materials, 2023. 62(7): p. 921-934.Search in Google Scholar
Gao, Y., et al., Toward single-layer uniform hexagonal boron nitride–graphene patchworks with zigzag linking edges. Nano letters, 2013. 13(7): p. 3439-3443.Search in Google Scholar
Berger, C., et al., Electronic confinement and coherence in patterned epitaxial graphene. Science, 2006. 312(5777): p. 1191-1196.Search in Google Scholar
Wei, C., et al., Turbostratic multilayer graphene synthesis on CVD graphene template toward improving electrical performance. Japanese Journal of Applied Physics, 2019. 58(SI): p. SIIB04.Search in Google Scholar
Narayanam, P.K., et al., Growth and Photocatalytic Behaviour of Transparent Reduced GOZnO Nanocomposite Sheets. Nanotechnology, 2019.Search in Google Scholar
Uthale, S.A., et al., Polymeric hybrid nanocomposites processing and finite element modeling: An overview. Science Progress, 2021. 104(3): p. 00368504211029471.Search in Google Scholar
Pei, S. and H.-M. Cheng, The reduction of graphene oxide. Carbon, 2012. 50(9): p. 3210-3228.Search in Google Scholar
Chu, K., et al., Thermal properties of graphene/metal composites with aligned graphene. Materials & Design, 2018. 140: p. 85-94.Search in Google Scholar
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 Scholar
Gaharwar, A.K., N.A. Peppas, and A. Khademhosseini, Nanocomposite hydrogels for biomedical applications. Biotechnology and bioengineering, 2014. 111(3): p. 441-453.Search in Google Scholar
Mittal, G., et al., A review on carbon nanotubes and graphene as fillers in reinforced polymer nanocomposites. Journal of Industrial and Engineering Chemistry, 2015. 21: p. 11-25.Search in Google Scholar
Kaseem, M., K. Hamad, and Y.G. Ko, Fabrication and materials properties of polystyrene/carbon nanotube (PS/CNT) composites: a review. European Polymer Journal, 2016. 79: p. 36-62.Search in Google Scholar
Taherian, R., et al. The Optimization of Ball Milling Method in Preparation of Phenolic/Functionalized Multi-wall Carbon Nanotube Composite and Comparison with Wet Method. in International Journal of Engineering Research in Africa. 2011. Trans Tech Publ.Search in Google Scholar
Naraghi, M., Graphitic Carbon Nanomaterials for Multifunctional Nanocomposites. Smart Composites: Mechanics and Design, 2013: p. 77.Search in Google Scholar
Jehoulet, C., et al., Electrochemistry and Langmuir trough studies of fullerene C60 and C70 films. Journal of the American Chemical Society, 1992. 114(11): p. 4237-4247.Search in Google Scholar
Kuruba, P. and N. Dushyantha, Polygon based topology formation and information gathering in satellite based wireless sensor network. Wireless Personal Communications, 2020. 115(1): p. 203-237.Search in Google Scholar
Mio, T., et al., Synthesis of a hemispherical geodesic phenine framework by a polygon assembling strategy. Angewandte Chemie, 2020. 132(16): p. 6629-6633.Search in Google Scholar
Kuruba, P. and N. Dushyantha, Stability Control in Polygon Based Topology Formation and Information Gathering in Satellite Based Wireless Sensor Network. Wireless Personal Communications, 2021. 120(4): p. 2491-2518.Search in Google Scholar
Devi, N., et al., Carbon-Based Nanomaterials: Carbon Nanotube, Fullerene, and Carbon Dots, in Nanomaterials: Advances and Applications. 2023, Springer. p. 27-57.Search in Google Scholar
Shilpi, S., et al., Functionalized Carbon Nanotubes, Graphene Oxide, Fullerenes, and Nanodiamonds: Emerging Theranostic Nanomedicines, in Multifunctional And Targeted Theranostic Nanomedicines: Formulation, Design And Applications. 2023, Springer. p. 187-213.Search in Google Scholar
Balaji, K., K. Shirvanimoghaddam, and M. Naebe, Multifunctional basalt fiber polymer composites enabled by carbon nanotubes and graphene. Composites Part B: Engineering, 2024. 268: p. 111070.Search in Google Scholar
Han, C., et al., In Situ‐Fabricated 2D/2D Heterojunctions of Ultrathin SiC/Reduced Graphene Oxide Nanosheets for Efficient CO2 Photoreduction with High CH4 Selectivity. ChemSusChem, 2018. 11(24): p. 4237-4245.Search in Google Scholar
Chen, K., Z. Xu, and X. Yang, Graphene Oxide-Induced Structural Morphology and Colloidal Interaction at Water-Oil Interface. Journal of Molecular Liquids, 2022: p. 119854.Search in Google Scholar
Belokda, F., A. Jellal, and E.H. Atmani, Electron scattering of inhomogeneous gap in graphene quantum dots. Physics Letters A, 2022: p. 128325.Search in Google Scholar
Li, M., et al., The effect of defects on the interfacial mechanical properties of graphene/epoxy composites. RSC advances, 2017. 7(73): p. 46101-46108.Search in Google Scholar
Yuan, H., et al., Surface modification of BNNS bridged by graphene oxide and Ag nanoparticles: A strategy to get balance between thermal conductivity and mechanical property. Composites Communications, 2021. 27: p. 100851.Search in Google Scholar
Mahmoud, K.A., et al., Functional graphene nanosheets: The next generation membranes for water desalination. Desalination, 2015. 356: p. 208-225.Search in Google Scholar
Yu, Z., et al., Shape memory epoxy polymer (SMEP) composite mechanical properties enhanced by introducing graphene oxide (GO) into the matrix. Materials, 2019. 12(7): p. 1107.Search in Google Scholar
Huskić, M., et al., One-step surface modification of graphene oxide and influence of its particle size on the properties of graphene oxide/epoxy resin nanocomposites. European polymer journal, 2018. 101: p. 211-217.Search in Google Scholar
Pathak, A.K., et al., Improved mechanical properties of carbon fiber/graphene oxide-epoxy hybrid composites. Composites Science and Technology, 2016. 135: p. 28-38.Search in Google Scholar
Han, X., et al., Effect of graphene oxide addition on the interlaminar shear property of carbon fiber-reinforced epoxy composites. New Carbon Materials, 2017. 32(1): p. 48-55.Search in Google Scholar
Malik, K., et al., Mechanical property enhancement of graphene-kenaf-epoxy multiphase composites for automotive applications. Composites Part A: Applied Science and Manufacturing, 2024. 177: p. 107916.Search in Google Scholar
Zanjani, J.S.M., et al., Tailoring viscoelastic response, self-heating and deicing properties of carbon-fiber reinforced epoxy composites by graphene modification. Composites Part A: Applied Science and Manufacturing, 2018. 106: p. 1-10.Search in Google Scholar
Kaynan, O., L.M. Pérez, and A. Asadi, Cellulose nanocrystal-enabled Tailoring of the interface in carbon nanotube-and graphene nanoplatelet-carbon fiber polymer composites: Implications for structural applications. ACS Applied Nano Materials, 2022. 5(1): p. 1284-1295.Search in Google Scholar
Xu, N., et al., A Mussel-inspired Strategy for CNT/carbon Fiber Reinforced Epoxy Composite by Hierarchical Surface Modification. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021: p. 128085.Search in Google Scholar
Zhang, X., et al., Interfacial microstructure and properties of carbon fiber composites modified with graphene oxide. ACS applied materials & interfaces, 2012. 4(3): p. 1543-1552.Search in Google Scholar
Yao, X., et al., Comparison of carbon nanotubes and graphene oxide coated carbon fiber for improving the interfacial properties of carbon fiber/epoxy composites. Composites Part B: Engineering, 2018. 132: p. 170-177.Search in Google Scholar
Menbari, S., et al., Viscoelastic response and interlaminar delamination resistance of epoxy/glass fiber/functionalized graphene oxide multi-scale composites. Polymer Testing, 2016. 54: p. 186-195.Search in Google Scholar
Wang, C., et al., Improving the mechanical, electrical, and thermal properties of polyimide by incorporating functionalized graphene oxide. High Performance Polymers, 2016. 28(7): p. 800-808.Search in Google Scholar
He, Y., et al., Micro-crack behavior of carbon fiber reinforced Fe3O4/graphene oxide modified epoxy composites for cryogenic application. Composites Part A: Applied Science and Manufacturing, 2018. 108: p. 12-22.Search in Google Scholar
He, Y., et al., Reinforced carbon fiber laminates with oriented carbon nanotube epoxy nanocomposites: magnetic field assisted alignment and cryogenic temperature mechanical properties. Journal of colloid and interface science, 2018. 517: p. 40-51.Search in Google Scholar
Song, B., et al., Interfacially reinforced carbon fiber/epoxy composite laminates via in-situ synthesized graphitic carbon nitride (g-C3N4). Composites Part B: Engineering, 2019. 158: p. 259-268.Search in Google Scholar
Wang, C., et al., Silver nanoparticles/graphene oxide decorated carbon fiber synergistic reinforcement in epoxy-based composites. Polymer, 2017. 131: p. 263-271.Search in Google Scholar
Ko, W.-Y., et al., Vertically standing MnO2 nanowalls grown on AgCNT-modified carbon fibers for high-performance supercapacitors. ACS Sustainable Chemistry & Engineering, 2018. 7(1): p. 669-678.Search in Google Scholar
Wang, C., et al., Controlled growth of silver nanoparticles on carbon fibers for reinforcement of both tensile and interfacial strength. RSC advances, 2016. 6(17): p. 14016-14026.Search in Google Scholar
Zhang, R., et al., Enhanced mechanical properties of multiscale carbon fiber/epoxy composites by fiber surface treatment with graphene oxide/polyhedral oligomeric silsesquioxane. Composites Part A: Applied Science and Manufacturing, 2016. 84: p. 455-463.Search in Google Scholar
Wu, G., et al., Interfacial properties and impact toughness of methylphenylsilicone resin composites by chemically grafting POSS and tetraethylenepentamine onto carbon fibers. Composites Part A: Applied Science and Manufacturing, 2016. 84: p. 1-8.Search in Google Scholar
Jiang, D., et al., Enhanced mechanical properties and anti-hydrothermal ageing behaviors of unsaturated polyester composites by carbon fibers interfaced with POSS. Composites Science and Technology, 2015. 117: p. 168-175.Search in Google Scholar
Zhang, C., G. Wu, and H. Jiang, Tuning interfacial strength of silicone resin composites by varying the grafting density of octamaleamic acid-POSS modified onto carbon fiber. Composites Part A: Applied Science and Manufacturing, 2018. 109: p. 555-563.Search in Google Scholar
Li, N., et al., One-pot strategy for covalent construction of POSS-modified silane layer on carbon fiber to enhance interfacial properties and anti-hydrothermal aging behaviors of PPBES composites. Journal of Materials Science, 2018. 53(24): p. 16303-16317.Search in Google Scholar
Kafi, A., et al., Surface treatment of carbon fibres for interfacial property enhancement in composites via surface deposition of water soluble POSS nanowhiskers. Polymer, 2018. 137: p. 97-106.Search in Google Scholar
Qiu, S., et al., Wettability of a single carbon fiber. Langmuir, 2016. 32(38): p. 9697-9705.Search in Google Scholar
Tareq, M.S., et al., Investigation of the flexural and thermomechanical properties of nanoclay/graphene reinforced carbon fiber epoxy composites. Journal of Materials Research, 2019. 34(21): p. 3678-3687.Search in Google Scholar
Jahangiri, A.A. and Y. Rostamiyan, Mechanical properties of nano-silica and nano-clay composites of phenol formaldehyde short carbon fibers. Journal of Composite Materials, 2020. 54(10): p. 1339-1352.Search in Google Scholar
Islam, M.E., et al., Characterization of carbon fiber reinforced epoxy composites modified with nanoclay and carbon nanotubes. Procedia Engineering, 2015. 105: p. 821-828.Search in Google Scholar
Cho, B.-G., et al., The effects of plasma surface treatment on the mechanical properties of polycarbonate/carbon nanotube/carbon fiber composites. Composites Part B: Engineering, 2019. 160: p. 436-445.Search in Google Scholar
Ling, Y., et al., Silicone-grafted epoxy/carbon fiber composites with superior mechanical/ablation performance. Materials Chemistry and Physics, 2022. 275: p. 125283.Search in Google Scholar
Abhishek, K., et al., A Study on Mechanical Attributes of Epoxy-Carbon Fiber-Terminalia bellirica Embedded Hybrid Composites, in Recent Advances in Smart Manufacturing and Materials. 2021, Springer. p. 163-173.Search in Google Scholar
Saccani, A., M. Fiorini, and S. Manzi, Recycling of Wastes Deriving from the Production of Epoxy-Carbon Fiber Composites in the Production of Polymer Composites. Applied Sciences, 2022. 12(9): p. 4287.Search in Google Scholar
Yeh, R.-Y., et al., Preparation and Degradation of Waste Polycarbonate-Derived Epoxy Thermosets and Composites. ACS Applied Polymer Materials, 2021. 4(1): p. 413-424.Search in Google Scholar
Xiao, W., et al. Detection of Delamination Defects in Carbon Fiber Composites based on Infrared Thermal Imaging. in 2021 Global Reliability and Prognostics and Health Management (PHM-Nanjing). 2021. IEEE.Search in Google Scholar
Karger-Kocsis, J., H. Mahmood, and A. Pegoretti, Recent advances in fiber/matrix interphase engineering for polymer composites. Progress in Materials Science, 2015. 73: p. 1-43.Search in Google Scholar
Nurazzi, N., et al., Mechanical Performance and Applications of CNTs Reinforced Polymer Composites—A Review. Nanomaterials, 2021. 11(9): p. 2186.Search in Google Scholar
Ghenaatian, H.R., et al., The Interaction of Deep Eutectic Solvents with Pristine Carbon Nanotubes and Their Associated Defects: A Density Functional Theory Study. Journal of Molecular Liquids, 2022: p. 119855.Search in Google Scholar
Agasti, N., et al., Carbon nanotube based magnetic composites for decontamination of organic chemical pollutants in water: A review. Applied Surface Science Advances, 2022. 10: p. 100270.Search in Google Scholar
Haghgoo, M., R. Ansari, and M. Hassanzadeh-Aghdam, Prediction of electrical conductivity of carbon fiber-carbon nanotube-reinforced polymer hybrid composites. Composites Part B: Engineering, 2019. 167: p. 728-735.Search in Google Scholar
Lee, S., et al., Preparation and properties of carbon fiber/carbon nanotube wet-laid composites. Polymers, 2019. 11(10): p. 1597.Search in Google Scholar
Anthony, D.B., et al., Applying a potential difference to minimise damage to carbon fibres during carbon nanotube grafting by chemical vapour deposition. Nanotechnology, 2017. 28(30): p. 305602.Search in Google Scholar
Zakaria, M.R., et al., Improving flexural and dielectric properties of carbon fiber epoxy composite laminates reinforced with carbon nanotubes interlayer using electrospray deposition. Nanotechnology Reviews, 2020. 9(1): p. 1170-1182.Search in Google Scholar
Battisti, A., et al., Single fiber push-out characterization of interfacial properties of hierarchical CNT-carbon fiber composites prepared by electrophoretic deposition. Composites science and technology, 2014. 95: p. 121-127.Search in Google Scholar
Rong, H., et al., Comparison of chemical vapor deposition and chemical grafting for improving the mechanical properties of carbon fiber/epoxy composites with multi-wall carbon nanotubes. Journal of Materials Science, 2013. 48(14): p. 4834-4842.Search in Google Scholar
Zakaria, M.R., et al., Hybrid carbon fiber-carbon nanotubes reinforced polymer composites: A review. Composites Part B: Engineering, 2019. 176: p. 107313.Search in Google Scholar
Yasin, G., et al., Metallic nanocomposite coatings, in Corrosion protection at the nanoscale. 2020, Elsevier. p. 245-274.Search in Google Scholar
Verma, K., et al., Modeling and simulation of electrophoretic deposition coatings. Journal of Computational Science, 2020. 41: p. 101075.Search in Google Scholar
Atiq Ur Rehman, M., et al., Electrophoretic deposition of carbon nanotubes: recent progress and remaining challenges. International Materials Reviews, 2021. 66(8): p. 533-562.Search in Google Scholar
Lee, S.-B., et al., Processing and characterization of multi-scale hybrid composites reinforced with nanoscale carbon reinforcements and carbon fibers. Composites Part A: Applied Science and Manufacturing, 2011. 42(4): p. 337-344.Search in Google Scholar
Tehrani, M., et al., Mechanical characterization and impact damage assessment of a woven carbon fiber reinforced carbon nanotube–epoxy composite. Composites Science and Technology, 2013. 75: p. 42-48.Search in Google Scholar
Kamae, T. and L.T. Drzal, Carbon fiber/epoxy composite property enhancement through incorporation of carbon nanotubes at the fiber–matrix interphase–Part I: The development of carbon nanotube coated carbon fibers and the evaluation of their adhesion. Composites Part A: Applied Science and Manufacturing, 2012. 43(9): p. 1569-1577.Search in Google Scholar
Drzal, L., N. Sugiura, and D. Hook, The role of chemical bonding and surface topography in adhesion between carbon fibers and epoxy matrices. Composite Interfaces, 1996. 4(5): p. 337-354.Search in Google Scholar
Gopal, J., M. Muthu, and I. Sivanesan, A Comprehensive Compilation of Graphene/Fullerene Polymer Nanocomposites for Electrochemical Energy Storage. Polymers, 2023. 15(3): p. 701.Search in Google Scholar
Kausar, A., Fullerene nanofiller reinforced epoxy nanocomposites—Developments, progress and challenges. Materials Research Innovations, 2021. 25(3): p. 175-185.Search in Google Scholar
Pikhurov, D. and V.V. Zuev. The effect of fullerene C60 on the mechanical and dielectrical behavior of epoxy resins at low loading. in AIP Conference Proceedings. 2014. American Institute of Physics. Vol.1599, No. 1, pp. 453-456Search in Google Scholar
Marjanović, M., et al., Inorganic fullerene-like nanoparticles and nanotubes of tungsten disulfide as reinforcement of carbon-epoxy composites. Fullerenes, Nanotubes and Carbon Nanostructures, 2021: p. 1-11.Search in Google Scholar
Jeyranpour, F., G. Alahyarizadeh, and A. Minuchehr, The thermo-mechanical properties estimation of fullerene-reinforced resin epoxy composites by molecular dynamics simulation–A comparative study. Polymer, 2016. 88: p. 9-18.Search in Google Scholar
Jiang, Z., et al., Improved bonding between PAN-based carbon fibers and fullerene-modified epoxy matrix. Composites Part A: Applied Science and Manufacturing, 2008. 39(11): p. 1762-1767.Search in Google Scholar
Ogasawara, T., Y. Ishida, and T. Kasai, Mechanical properties of carbon fiber/fullerene-dispersed epoxy composites. Composites Science and Technology, 2009. 69(11-12): p. 2002-2007.Search in Google Scholar
Shang, C., et al., Effect of network size on mechanical properties and wear resistance of titanium/nanodiamonds nanocomposites with network architecture. Composites Communications, 2020. 19: p. 74-81.Search in Google Scholar
Nieto, A., et al., Elevated temperature wear behavior of thermally sprayed WCCo/nanodiamond composite coatings. Surface and Coatings Technology, 2017. 315: p. 283-293.Search in Google Scholar
Kim, S.-H., K.Y. Rhee, and S.-J. Park, Amine-terminated chain-grafted nanodiamond/epoxy nanocomposites as interfacial materials: Thermal conductivity and fracture resistance. Composites Part B: Engineering, 2020. 192: p. 107983.Search in Google Scholar
Zhang, Y., K.Y. Rhee, and S.-J. Park, Nanodiamond nanocluster-decorated graphene oxide/epoxy nanocomposites with enhanced mechanical behavior and thermal stability. Composites Part B: Engineering, 2017. 114: p. 111-120.Search in Google Scholar
Reina, G., et al., Chemical functionalization of nanodiamonds: Opportunities and challenges ahead. Angewandte Chemie International Edition, 2019. 58(50): p. 17918-17929.Search in Google Scholar
Singh, B. and A. Mohanty, Influence of Nanodiamonds on the Mechanical Properties of Glass Fiber-/Carbon Fiber-Reinforced Polymer Nanocomposites. Journal of Materials Engineering and Performance, 2021: p. 1-12.Search in Google Scholar
Aris, A., A. Shojaei, and R. Bagheri, Cure kinetics of nanodiamond-filled epoxy resin: influence of nanodiamond surface functionality. Industrial & Engineering Chemistry Research, 2015. 54(36): p. 8954-8962.Search in Google Scholar
Farooq, U., et al., Improved Ablative Properties of Nanodiamond-Reinforced Carbon Fiber– Epoxy Matrix Composites. Polymers, 2021. 13(13): p. 2035.Search in Google Scholar
Banger, A., et al., Synthetic Methods and Applications of Carbon Nanodots. Catalysts, 2023. 13(5): p. 858.Search in Google Scholar
Peng, J., et al., Graphene quantum dots derived from carbon fibers. Nano letters, 2012. 12(2): p. 844-849.Search in Google Scholar
Jing, H.H., et al., Green carbon dots: Synthesis, characterization, properties and biomedical applications. Journal of Functional Biomaterials, 2023. 14(1): p. 27.Search in Google Scholar
Chen, R., et al., Ultra‐Narrow‐Bandwidth Deep‐Red Electroluminescence Based on Green Plant‐Derived Carbon Dots. Advanced Materials, 2023: p. 2302275.Search in Google Scholar
Wang, B., G.I. Waterhouse, and S. Lu, Carbon dots: mysterious past, vibrant present, and expansive future. Trends in Chemistry, 2023.Search in Google Scholar
Chen, W., et al., Synthesis and applications of graphene quantum dots: a review. Nanotechnology Reviews, 2018. 7(2): p. 157-185.Search in Google Scholar
Yuan, X., et al., Influence of different surface treatments on the interfacial adhesion of graphene oxide/carbon fiber/epoxy composites. Applied Surface Science, 2018. 458: p. 996-1005.Search in Google Scholar
Chu, C., et al., Interfacial microstructure and mechanical properties of carbon fiber composite modified with carbon dots. Composites Science and Technology, 2019. 184: p. 107856.Search in Google Scholar
Islam, M.S., et al., In-situ direct grafting of graphene quantum dots onto carbon fibre by low temperature chemical synthesis for high performance flexible fabric supercapacitor. Materials Today Communications, 2017. 10: p. 112-119.Search in Google Scholar
Fang, J., et al., Co-deposition of carbon dots and reduced graphene oxide nanosheets on carbon-fiber microelectrode surface for selective detection of dopamine. Applied Surface Science, 2017. 412: p. 131-137.Search in Google Scholar
de Oliveira, D.M.G., V.V. Gonçalves, and A.A. dos Santos Junior, Modeling the effect of microscale residual stresses on acoustoelasticity for carbon fiber composites. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 2024. 46(1): p. 25.Search in Google Scholar
Das, T.K., P. Ghosh, and N.C. Das, Preparation, development, outcomes, and application versatility of carbon fiber-based polymer composites: a review. Advanced Composites and Hybrid Materials, 2019. 2: p. 214-233.Search in Google Scholar
Durham, S. and W. Padgett, Cumulative damage models for system failure with application to carbon fibers and composites. Technometrics, 1997. 39(1): p. 34-44.Search in Google Scholar
Saito, N., et al., Application of carbon fibers to biomaterials: a new era of nano-level control of carbon fibers after 30-years of development. Chemical Society Reviews, 2011. 40(7): p. 3824-3834.Search in Google Scholar
Chiou, Y.-C., H.-Y. Chou, and M.-Y. Shen, Effects of adding graphene nanoplatelets and nanocarbon aerogels to epoxy resins and their carbon fiber composites. Materials & Design, 2019. 178: p. 107869.Search in Google Scholar
Zhao, W., et al., Mechanical behaviors and applications of shape memory polymer and its composites. Applied Physics Reviews, 2023. 10(1).Search in Google Scholar
Yang, H., et al., Properties and mechanism of two-way shape memory polyurethane composite under stress-free condition. Advanced Composites and Hybrid Materials, 2023. 6(1): p. 1.Search in Google Scholar
Paik, I.H., et al., Development and application of conducting shape memory polyurethane actuators. Smart Materials and Structures, 2006. 15(5): p. 1476.Search in Google Scholar
Li, Z., et al., Shape memory epoxy resin and its composite with good shape memory performance and high mechanical strength. Polymer Bulletin, 2023. 80(2): p. 1641-1655.Search in Google Scholar
Gall, K., et al., Carbon fiber reinforced shape memory polymer composites. Journal of intelligent material systems and structures, 2000. 11(11): p. 877-886.Search in Google Scholar
Leng, J., et al., Shape-memory polymers and their composites: stimulus methods and applications. Progress in Materials Science, 2011. 56(7): p. 1077-1135.Search in Google Scholar
Ge, Q., et al., Multimaterial 4D printing with tailorable shape memory polymers. Scientific reports, 2016. 6(1): p. 31110.Search in Google Scholar
Leng, J., et al., Electroactivate shape-memory polymer filled with nanocarbon particles and short carbon fibers. Applied Physics Letters, 2007. 91(14).Search in Google Scholar
Xie, S., et al., Recent Advances toward Achieving High‐Performance Carbon‐Fiber Materials for Supercapacitors. ChemElectroChem, 2018. 5(4): p. 571-582.Search in Google Scholar
Kim, J.H., et al., Nanocellulose for energy storage systems: beyond the limits of synthetic materials. Advanced Materials, 2019. 31(20): p. 1804826.Search in Google Scholar
Pour, G.B., et al., CNTs-Supercapacitors: A Review of Electrode Nanocomposites Based on CNTs, Graphene, Metals, and Polymers. Symmetry, 2023. 15(6): p. 1179.Search in Google Scholar
Qian, H., et al., Multifunctional structural supercapacitor composites based on carbon aerogel modified high performance carbon fiber fabric. ACS applied materials & interfaces, 2013. 5(13): p. 6113-6122.Search in Google Scholar
Chen, Y., et al., Nanocellulose/polypyrrole aerogel electrodes with higher conductivity via adding vapor grown nano-carbon fibers as conducting networks for supercapacitor application. RSC advances, 2018. 8(70): p. 39918-39928.Search in Google Scholar
Hsiao, Y.-J. and L.-Y. Lin, Enhanced surface area, graphene quantum dots, and functional groups for the simple acid-treated carbon fiber electrode of flexible fiber-type solid-state supercapacitors without active materials. ACS Sustainable Chemistry & Engineering, 2020. 8(6): p. 2453-2461.Search in Google Scholar
Hiremath, N., J. Mays, and G. Bhat, Recent developments in carbon fibers and carbon nanotube-based fibers: a review. Polymer reviews, 2017. 57(2): p. 339-368.Search in Google Scholar
Ali, Z., et al., Preparation, properties and mechanisms of carbon fiber/polymer composites for thermal management applications. Polymers, 2021. 13(1): p. 169.Search in Google Scholar
Fang, Z., et al., Through-thickness thermal conductivity enhancement of carbon fiber composite laminate by filler network. International Journal of Heat and Mass Transfer, 2019. 137: p. 1103-1111.Search in Google Scholar
Lu, Y., et al., Strengthening and toughening behaviours and mechanisms of carbon fiber reinforced polyetheretherketone composites (CF/PEEK). Composites Communications, 2023. 37: p. 101397.Search in Google Scholar
Hermansson, F., et al., Climate impact and energy use of structural battery composites in electrical vehicles—a comparative prospective life cycle assessment. The International Journal of Life Cycle Assessment, 2023. 28(10): p. 1366-1381.Search in Google Scholar
Kumar, N., A.K. Gangwar, and K.S. Devi, Carbon fibers in biomedical applications. Recent Developments in the Field of Carbon Fibers, 2018: p. 83-102.Search in Google Scholar
