The study aims to enhance the performance of epoxy composites by incorporating various carbon-based materials, including 3D carbon felt (3DCFs), graphene oxide-carbon felt hybrids (GO@3DCFs), multi-walled carbon nanotubes combined with graphene oxide (MWCNTs-GO@3DCFs), and helical carbon nanotubes combined with graphene oxide (HCNTs-GO@3DCFs). Most epoxy composites are favored in use because of their good mechanical properties but their performance is usually restricted due to low stiffness, lack of thermal stability, and impact resistance. There are not enough studies focusing on the synthesis and performance improvement of epoxy composites with multi-scale carbon nanomaterials incorporated simultaneously in a systematic manner. To fill this gap, we employed Dynamic mechanical analysis and flexural testing as additional methods to understand how the different carbon fillers affect the storage modulus, glass transition temperature (Tg), flexural strength, and impact resistance of the composites. The study provides improvements considering in particular the increase of storage modulus of 154% as well as Tg of 30°C with MWCNTs-GO@3DCFs addition. Likewise, the increase was also observed when measuring the flexural strength and impact resistance, where the MWCNTs-GO@CFs reached a flexural strength of 251 MPa and impact strength of 21.6 kJ/m2. As for the HCNTs-GO@CFs, they recorded a flexural strength of 231 MPa and an impact strength of 25.3 kJ/m2. The reason for the improved performance is due to the nature of the carbon nanomaterials combined. More specifically, there is an improvement in load bearing, stress distribution, and performance of composite when HCNTs, MWCNTs, and GO are provided as a dense network.
AliZYaqoobSYuJ, et al.“Critical review on the characterization, preparation, and enhanced mechanical, thermal, and electrical properties of carbon nanotubes and their hybrid filler polymer composites for various applications”. Composites Part C: Open Access2024; 13: 100434.
2.
KaliappanSNatrayanL. “Impact of Kenaf fiber and inorganic nanofillers on mechanical properties of epoxy-based nanocomposites for sustainable automotive applications”. SAE technical paper 2023-01-5115, 2024. https://doi.org/10.4271/2023-01-5115
3.
AliKGMuhmmedAATaiehNK, et al.“Tribological and mechanical performance of epoxy reinforced by fish scales powder”. Rev Compos Matériaux Avancés2022; 32: 149.
4.
BattawiAAl FilfilyAAbedB. Finite element simulation of buckling behavior of epoxy composite plate reinforced with nano-Al particles. International Journal on Technical and Physical Problems of Engineering (IJTPE). 2022; 52: 144–149.
5.
BattawiAAAbedBAl-FilfilyAA. Enhancements of Creep Compliance of Kevlar and Carbon Fibers Reinforced Sika Epoxy Composites. Revue des Composites et des Materiaux Avances. 2024; 34(5): 593.
6.
AbbasMRKadhim TaiehNAlmuhaisenAN, et al.“Harnessing 3D porous cobalt oxide Nanoflakes grown on metal for exceptional adhesion between aluminum surfaces and the epoxy matrix”. Adv Eng Mater: 2401732.
7.
TaiehNKHakeemHSKadhimMS, et al.“Optimizing mechanical performance in woven basalt fibers/epoxy composites: using silane coupling agents to modify epoxy resin for fiber-matrix interface”. J Inorg Organomet Polym Mater2024; 35: 680–696.
8.
IslamTChaionMHJalilMA, et al. “Advancements and challenges in natural fiber‐reinforced hybrid composites: a comprehensive review”. SPE Polymers. 2024; 5(4): 481–506.
9.
ŞomoghiRSemenescuAPasăreV, et al.“The impact of ZnO nanofillers on the mechanical and anti-corrosion performances of epoxy composites”. Polymers2024; 16: 2054.
10.
YusufJSapuanSRashidU, et al.“Thermal, mechanical, t hermo‐mechanical and morphological properties of graphene nanoplatelets reinforced green epoxy nanocomposites”. Polym Compos2024; 45: 1998–2011.
11.
YazdanparastRRafieeRKalhoriH, et al.“Dynamic mechanical behavior of CNT-reinforced epoxy under medium-strain rate: a comparative study”. Compos Struct2024; 344: 118343.
12.
KadhimNMeiYWangY, et al.“Remarkable improvement in the mechanical properties of epoxy composites achieved by a small amount of modified helical carbon nanotubes”. Polymers2018; 10: 1103.
13.
LauK-t.LuMCheungH, et al.“Thermal and mechanical properties of single-walled carbon nanotube bundle-reinforced epoxy nanocomposites: the role of solvent for nanotube dispersion”. Compos Sci Technol2005; 65: 719–725.
14.
KarnatiSRAgboPZhangL. “Applications of silica nanoparticles in glass/carbon fiber-reinforced epoxy nanocomposite”. Compos Commun2020; 17: 32–41.
15.
BansalSAKhannaVSinghAP, et al.Small percentage reinforcement of carbon nanotubes (CNTs) in epoxy (bisphenol-A) for enhanced mechanical performance. Mater Today Proc2022; 61: 275–279.
16.
SuiYCuiYMengX, et al.“Research progress on the correlation between properties of nanoparticles and their dispersion states in polymer matrix”. J Appl Polym Sci2022; 139: 52096.
17.
MoradiAAnsariRHassanzadeh-AghdamM. “Synergistic effect of carbon nanotube/graphene nanoplatelet hybrids on the elastic and viscoelastic properties of polymer nanocomposites: finite element micromechanical modeling”. Acta Mech2024; 235: 1887–1909.
18.
SahuRPonnusamiSAWeimerC, et al.“Interface engineering of carbon fiber composites using CNT: a review”. Polym Compos2024; 45: 9–42.
19.
RashidABHaqueMIslamSM, et al. “Nanotechnology-enhanced fiber-reinforced polymer composites: recent advancements on processing techniques and applications”. Heliyon. 2024; 10(2).
20.
WuYAnCGuoY, et al.“Highly aligned graphene aerogels for multifunctional composites”. Nano-Micro Lett2024; 16: 118.
21.
BarriosEFoxDLi SipYY, et al.“Nanomaterials in advanced, high-performance aerogel composites: a review”. Polymers2019; 11: 726.
22.
LiuPTranTQFanZ, et al.“Formation mechanisms and morphological effects on multi-properties of carbon nanotube fibers and their polyimide aerogel-coated composites”. Compos Sci Technol2015; 117: 114–120.
23.
ZhaoWTrungVDLiH, et al.“Enhanced functionalization of nonwoven fabric by spray coating AgNPs/CNTs solution prepared by a one-step method”. Chem Eng J2024; 494: 153101.
24.
AnQRiderANThostensonET. “Electrophoretic deposition of carbon nanotubes onto carbon-fiber fabric for production of carbon/epoxy composites with improved mechanical properties”. Carbon2012; 50: 4130–4143.
25.
DongLHouFLiY, et al.“Preparation of continuous carbon nanotube networks in carbon fiber/epoxy composite”. Compos Appl Sci Manuf2014; 56: 248–255.
26.
MahmoodHSimoniniLDorigatoA, et al.“Graphene deposition on glass fibers by triboelectrification”. Appl Sci2021; 11: 3123.
27.
ZhiDLiTLiJ, et al.“A review of three-dimensional graphene-based aerogels: synthesis, structure and application for microwave absorption”. Compos B Eng2021; 211: 108642.
28.
ArabySQiuAWangR, et al.“Aerogels based on carbon nanomaterials”. J Mater Sci2016; 51: 9157–9189.
29.
WangZShenXAkbari GarakaniM, et al.“Graphene aerogel/epoxy composites with exceptional anisotropic structure and properties”. ACS Appl Mater Interfaces2015; 7: 5538–5549.
30.
LiYWeiWWangY, et al.“Construction of highly aligned graphene-based aerogels and their epoxy composites towards high thermal conductivity”. J Mater Chem C Mater2019; 7: 11783–11789.
31.
KadhimNZamanAJiangM, et al.“A cast-in-place fabrication of high performance epoxy composites cured in an in-situ synthesized 3D foam of nanofibers”. Compos B Eng2021; 205: 108495.
32.
ZamanAHuangFJiangM, et al.“Fabrication of enhanced epoxy composite by embedded hierarchical porous lignocellulosic foam”. Renew Energy2020; 150: 1066–1073.
33.
AliMMTaiehNKHusseinHA, et al.“Nanostructured Co3O4-graced 3D carbon felts for improved mechanical interlocking in epoxy composites: morphological and mechanical/tribological optimization”. J Mater Sci2024; 59: 7716–7732.
ChenYZhangH-BWangM, et al.“Phenolic resin-enhanced three-dimensional graphene aerogels and their epoxy nanocomposites with high mechanical and electromagnetic interference shielding performances”. Compos Sci Technol2017; 152: 254–262.
36.
HanLLiKLiuH, et al.“Heterogeneous stacking strategy towards carbon aerogel for thermal management and electromagnetic interference shielding”. Chem Eng J2023; 465: 142839.
37.
NayyefZJTaiehNKBeddaiAA, et al.“Mechanical characterization of nano‐SiO2‐reinforced epoxy sandwich composites with 3D rayon graphite felt core and woven carbon fiber face sheets”. Journal of Nanotechnology2025; 2025: 4194409.
38.
TaiehNKFahadEAA. Eco‐friendly enhancement of mechanical properties in 3D carbon felt reinforced epoxy/aluminum sandwich composites via NaCl‐based anodizing and triton X‐100 modification. Polym Compos. 2025; 46(3): 2466–2483.
39.
TaiehNKKhudhurSKFahadEAA, et al.“High mechanical performance of 3-aminopropyl triethoxy silane/epoxy cured in a sandwich construction of 3D carbon felts foam and woven basalt fibers”. Nanotechnol Rev2023; 12: 20220519.
40.
XuFCuiYBaoD, et al.“A 3D interconnected Cu network supported by carbon felt skeleton for highly thermally conductive epoxy composites”. Chem Eng J2020; 388: 124287.
41.
SinghBBharadwajPChoudharyV, et al.“Enhanced microwave shielding and mechanical properties of multiwall carbon nanotubes anchored carbon fiber felt reinforced epoxy multiscale composites”. Appl Nanosci2014; 4: 421–428.
42.
WuXGaoYJiangT, et al.“3D Thermal network supported by CF felt for improving the thermal performance of CF/C/epoxy composites”. Polymers2021; 13: 980.
43.
WangYMengFHuangF, et al. “Ultrastrong carbon nanotubes/graphene papers via multiple π–π cross-linking”. ACS Appl Mater Interfaces. 2020; 12(42): 47811–47819.
