This study investigates the thermal, mechanical, fire retardant and electrochemical properties of carbon (CPC) derived from coco peat, an agricultural biomass, reinforced Diglycidyl ether of bisphenol-A (DGEBA) epoxy resin composite. Composites were prepared by integrating1, 3 and 5 wt % of carbon with DGEBA resin. Both CPC and DGEBA - CPC composites were analysed by Fourier Transform InfraRed (FTIR) spectroscopy, Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM) and X-Ray Diffraction (XRD) techniques. Thermal stability of CPC and composites were examined by Thermo Gravimetric Analysis (TGA) and results show that CPC is highly stable and DGEBA-5 wt % CPC composite withstand temperature up to 375°C and produces 15% char residue at 900°C. Mechanical performances such as tensile strength and hardness were tested in accordance with ASTM D3039 and ASTM D2240 standards. Flammability of CPC-DGEBA composites by UL-94 burning test indicate that 5 wt % CPC composite possesses improved fire retardancy with V2 rating having a LOI value of 26.2. Electrochemical performances of CPC and composites were evaluated by Cyclic Voltammetry (CV) studies and results prove the current carrying ability of CPC and composites.
DobrzanskiLA. Significance of materials science for the future development of societies. J Mater Process Technol2006; 175: 133–148.
2.
BeheraA. Biomaterials. Advanced Materials. Springer, 2024, pp. 439–467.
3.
KhanFHossainNMimJJ, et al.Advances of composite materials in automobile applications – a review. J Eng Res2024; (article in press). DOI: 10.1016/j.jer.2024.02.017.
4.
AkterRSultanaRAlamZ, et al.Fabrication and characterization of woven natural fibre reinforced unsaturated polyester resin composites. Int J Eng Technol2013; 13: 122–128.
5.
OlanrewajuOOladeleIOAdelaniSO. Recent advances in natural fiber reinforced metal/ceramic/polymer composites: an overview of the structure-property relationship for engineering applications. Hybrid Adv2025; 8: 100378.
6.
AnsariMOOvesMSalahN, et al.DC electrical conductivity retention and antibacterial aspects of microwave-assisted ultrathin CuO@polyaniline composite. Chem Pap2020; 74: 3887–3898.
7.
MaQZouDWangY, et al.Preparation and properties of novel ceramic composites based on microencapsulated phase change materials (MEPCMs) with high thermal stability. Ceram Int2021; 47: 24240–24251.
8.
PanZHanSWangJ, et al.Polyimide fabric-reinforced polyimide matrix composites with excellent thermal, mechanical, and dielectric properties. High Perform Polym2020; 32: 1085–1093.
9.
ZhaoGFanYTangC, et al.Preparation and compressive properties of cementitious composites reinforced by 3D printedcellular structures with a negative Poisson’s ratio. Dev Built Environ2024; 17: 100362.
10.
DeekshaBSadanandVHariramN, et al.Preparation and properties of cellulose nanocomposite fabrics with in situ generated silver nanoparticles by bio reduction method. J Bioresour Bioprod2021; 6: 75–81.
11.
BrunnerAJ. Identification of damage mechanisms in fiber-reinforced polymer-matrix composites with acoustic emission and the challenge of assessing structural integrity and service life. Constr Build Mater2018; 173: 629–637.
12.
WrightWW. Polymers in aerospace applications. Mater Des1991; 12: 222–227.
13.
ChandramohanDBharanichandarJKarthikeyanP, et al.Progress of biomaterials in the field of Orthopedics. Am J Appl Sci2014; 11: 623–630.
14.
EdwardsEBrantleyCRuffinPB. Overview of nanotechnology in military and aerospace applications. Nanotechnol Commercialization2017: 133–176.
15.
VelenturfAPMPurnellP. Principles for a sustainable circular economy. Sustain Prod Consum2021; 27: 1437–1457.
16.
OrtegaFVersinoFLópezOV, et al.Biobased composites from agro-industrial wastes and by-products. Emerg Mater2022; 5: 873–921.
17.
MogheisehMKarimianRKhoshsefatM. Vanillin-derived epoxy monomer for synthesis of bio-based epoxy thermosets: effect of functionality on thermal, mechanical, chemical and structural properties. Chem Pap2020; 74: 3347–3358.
18.
HussainFHojjatiMOkamotoM, et al.Review article: polymer-matrix nanocomposites, processing, manufacturing, and application: an overview. J Compos Mater2006; 40: 1511–1575.
19.
GuHMaCGuJ, et al.An overview of multifunctional epoxy nanocomposites. J Mater Chem C2016; 4: 5890–5906.
20.
BairagiHVashishthPJiG, et al.Polymers and their composites for corrosion inhibition application: development, advancement, and future scope–A critical review. Corros Commun2024; 15: 79–94.
21.
LiuQZhaoYGaoS, et al.Recent advances in the flame retardancy role of graphene and its derivatives in epoxy resin materials. Compos A: Appl Sci Manuf2021; 149: 106539.
22.
BagheriRWilliamsMAPearsonRA. Use of surface modified recycled rubber particles for toughening of epoxy polymers. Polym Eng Sci1997; 37: 245–251.
23.
KinlochAJTaylorAC. Mechanical and fracture properties of epoxy/ inorganic micro- and nano-composites. J Mater Sci Lett2003; 22: 1439–1441.
24.
YangBLiXWangL, et al.An efficient flame retardant for epoxy resin: preparation and pyrolytic behaviour. High Perform Polym2019; 31: 1009–1019.
25.
PrauchnerMJRodríguez-ReinosoF. Chemical versus physical activation of coconut shell: a comparative study. Micropor Mesopor Mat2012; 152: 163–171.
26.
HasanKMFHorváthPGBakM, et al.A state-of-the-art review on coir fiber-reinforced biocomposites. RSC Adv2021; 11: 10548–10571.
27.
WangZXBarfordJPHuiCW, et al.Kinetic and equilibrium studies of hydrophilic and hydrophobic rice husk cellulosic fibers used as oil spill sorbents. Chem Eng J2015; 281: 961–969.
28.
KeerthikaBUmayavalliMJeyalalithaT, et al.Coconut shell powder as cost effective filler in copolymer of acrylonitrile and butadiene rubber. Ecotoxicol Environ Saf2016; 130: 1–3.
29.
JoshiRBajpaiPKMukhopadhyayS. Processing and performance evaluation of agro wastes reinforced bio-based epoxy hybrid composites, Proc. Inst. Mech. Eng. L: J. Mater.: Des. Appl2022; 237: 482–499.
30.
NanNDeVallanceDBXieX, et al.The effect of bio-carbon addition on the electrical, mechanical, and thermal properties of polyvinyl alcohol/biochar composites. J Compos Mater2015; 50: 1161–1168.
31.
Mlonka-MędralaAEvangelopoulosPSieradzkaM, et al.Pyrolysis of agricultural waste biomass towards production of gas fuel and high-quality char: experimental and numerical investigations. Fuel2021; 296: 120611.
32.
KavithaDChandrasekaran MurugavelSThenmozhiS. Flame retarding cardanol based novolac- epoxy/rice husk composites. Mater Chem Phys2021; 263: 124225.
33.
NakumuraSTsujiYYoshizawaK, et al.Role of hydrogen-bonding and OH−π interactions in the adhesion of epoxy resin on hydrophilic surfaces. ACS Omega2020; 5: 26211–26219.
34.
XuCZhengZWuW, et al.Design of healable epoxy composite based on β-hydroxyl esters crosslinked networks by using carboxylated cellulose nanocrystals as crosslinker. Compos Sci Technol2019; 181: 107677.
35.
KumarSFalzonBGKunJ, et al.High performance multiscale glass fibre epoxy composites integrated with cellulose nanocrystals for advanced structural applications. Appl Sci Manuf2020; 131: 105801.
36.
SinghKPSinghAKumarN, et al.Morphological features, dielectric and thermal properties of epoxy–copper cobaltite nanocomposites: preparation and characterization. Bull Mater Sci2020; 43: 114.
EralSOktayBDizmanC, et al.Preparation of organic–inorganic bio-based epoxy coatings with high anti-corrosive performance. Polym Bull2024; 81: 6873–6890.
39.
ThenmozhiSMurugavelSC. Investigation on mechanical, thermal, and flame retardant properties of particulate SiO2 reinforced cardanol based composites. Polym Compos2020; 41:1118–1134.
40.
SesukTTammawatPJivaganontP, et al.Activated carbon derived from coconut coir pith as high-performance supercapacitor electrode material. J Energy Storage2019; 25: 100910.
41.
VarunDArun KumarNReenaS, et al.Synthesis and characterization of Phenoxy modified epoxy blends. Mal Poly J2010; 5: 69–83.
42.
TudorachiNMustataF. Curing and thermal degradation of diglycidyl ether of bisphenol A epoxy resin crosslinked with natural hydroxy acids as environmentally friendly hardeners. Arab J Chem2020; 13: 671–682.
43.
ChowdhuryRAHosurMVNuruddinM, et al.Self-healing epoxy composites: preparation, characterization and healing performance. J Mater Res Technol2015; 4: 33–43.
44.
Men’shchikovIShkolinAKhozinaE, et al.Thermodynamics of adsorbed methane storage systems based on peat-derived activated carbons. Nanomaterials2020; 10: 1379.
45.
JilaniWGouadriaSBouzidiA, et al.DGEBA epoxy polymer composite panels (MB: DGEBA-EPCPs): structural, optical, and dielectric properties-leanings and appliances in optical electronics. Opt Quant Electron2023; 55: 257.
46.
YangLWangZYangL, et al.Coco peat powder as a source of magnetic sorbent for selective oil–water separation. Ind Crops Prod2017; 101: 1–10.
47.
TaylorDFKalachandraSSankarapandianM, et al.Relationship between filler and matrix resin characteristics and the properties of uncured composite pastes. Biomaterials1998; 19(1-3): 197–204.
48.
HuangJNieX. A simple and novel method to design flexible and transparent epoxy resin with tunable mechanical properties. Polym Int2016; 65: 835–840.
49.
MaSQLiuXQJiangY, et al.Synthesis and properties of phosphorus-containing bio-based epoxy resin from itaconic acid. Sci China Chem2014; 57: 379–388.
50.
YouGYHeHWFengB, et al.Synthesis and application of a novel phosphoryl thiourea-containing flame retardant for epoxy resin. Chem Pap2020; 74: 2403–2414.
51.
Van KrevelenDW. Some basic aspects of flame resistance of polymeric materials. Polymer1975; 16: 615–620.
52.
NatarajanMMurugavelSC. Cure kinetics of bio-based epoxy resin developed from epoxidized cardanol–formaldehyde and diglycidyl ether of bisphenol–A networks. J Therm Anal Calorim2016; 125: 387–396.
53.
KhanMMishraSRatnaD, et al.Investigation of thermal and mechanical properties of styrene–butadiene rubber nanocomposites filled with SiO2–polystyrene core–shell nanoparticles. J Compos Mater2020; 54: 1785–1795.
54.
DasCSKhodaAESSayeedAM, et al.On the use of wood charcoal filler to improve the properties of natural fiber reinforced polymer composites. Mater Today Proc2021; 44: 926–929.
55.
SudheerMPrabhuRRajuK, et al.Effect of filler content on the performance of epoxy/PTW composites. Adv Mater Sci Eng2014; 2014: 11. Article ID 970468. DOI: 10.1155/2014/970468.
56.
BenkhelladiALaouiciHBouchouchaA. Tensile and flexural properties of polymer composites reinforced by flax, jute and sisal fibres. Int J Adv Manuf Technol2020; 108: 895–916.
AkaluziaROEdoziunoFOAdediranAA, et al.Evaluation of the effect of reinforcement particle sizes on the impact and hardness properties of hardwood charcoal particulate- polyester resin composites. Mater Today Proc2021; 38: 570–577.
59.
RaoYSShivamurthyBMohanNS, et al.Investigation of tensile properties, hardness, and morphology of h-BN and MoS2 filler modified carbon fabric/epoxy composites. Cogent Eng2023; 10: 2178129.
60.
BharadwajaKRaoSSRaoTB. Investigation of hardness & tribology behavior of Epoxy and Sio2 composite: an experimental study. Mater Today Proc2021; 45: 3343–3347.
61.
QiBZhangQXBannisterM, et al.Investigation of the mechanical properties of DGEBA-based epoxy resin with nanoclay additives. Compos Struct2006; 75: 514–519.
62.
AckibasGOzcanSAckibasNC. Production and characterization of a hybrid polymer matrix composite. Polym Compos2018; 39: 4080–4093.
63.
KanaginahalGMTambrallimathVMurthyM, et al.Flammability studies of natural fiber-reinforced polymer composites fabricated by additive manufacturing technology: a review. J Inst Eng India Ser D2024; 105: 1291–1303.
64.
KrishnadeviKSelvarajV. Biowaste material reinforced cyanate ester based epoxy composites for flame retardant applications. High Perform Polym2016; 28: 881–894.
65.
NatarajanVKMadaswamySLWabaidurSM, et al.Ultrasonication assisted synthesis of nickel decorated poly(diphenylamine) composite based modified electrode for high performance methanol electro oxidation. J Mater Sci Mater Electron2022; 33: 25239–25249.
66.
KeertheeswariNVMadaswamySLWabaidurSM, et al.Platinum nanoparticles/phosphotungstic acid nanorods anchored poly(diphenylamine) nanohybrid coated electrode as a superior electro-catalyst for oxidation of methanol. Prog Org Coat2021; 161: 106470.
67.
NatarajanVKMadaswamySLAlsaiariNS, et al.Ultrasound-aided synthesis of nickel nanoparticles loaded on poly(2,5-dimethoxyaniline) nanocomposite towards improved methanol electro-oxidation application. Synt Met2022; 291: 117197.
68.
NatarajanVKMadaswamySLKrishnamoorthyN, et al.Ultrasonication-Assisted synthesis of nickel tungstate decorated on polydimethoxyaniline nanocomposite catalyst for potential direct methanol fuel cell application. ES Energy & Environ2023; 21: 926.
69.
NatarajanVKMadaswamySLmuteb AljuwayidA, et al.Ultrasound assisted synthesis of cobalt tungstate decorated Poly(2,5-dimethoxyaniline) nanocomposite towards improved methanol electro-oxidation. J Ind Eng Chem2023; 121: 480–488.
