This study aims to leverage the environmentally friendly characteristics of bio-based epoxy resin and natural modifiers while reducing dependence on synthetic materials. To achieve this, the bio-based GreenPoxy resin was modified with natural modifiers, and the resulting thermal and mechanical properties were evaluated. Milled cotton fibers and epoxidized soybean oil (ESO) were incorporated as natural reinforcement and plasticizer, respectively. Cotton content was varied from 0 to 15 wt%, while ESO content was fixed at 20 wt% based on prior studies indicating optimal toughening performance. Thermal analysis revealed that ESO addition slightly enhances the thermal stability of GreenPoxy by 4.9%, whereas cotton reduces it by 1.3%. Cotton modified GreenPoxy showed lower thermal degradation temperature and a reduced weight loss rate. In terms of mechanical performance, cotton addition in GreenPoxy resulted in significant improvement in impact strength, with a 20.8% increase, followed by ESO addition with 12.8% increase. The highest impact strength improvement of 23% was achieved in GreenPoxy with a combination of 5 wt% cotton and 20 wt% ESO. Conversely, the tensile strength of GreenPoxy decreased slightly by 3.4% with cotton addition and more significantly by 19.6% with ESO addition. Increasing cotton content further reduced tensile strength, reaching a 32.8% decrease compared to neat GreenPoxy. These results revealed that the combined use of low cotton content and ESO effectively enhances impact resistance while maintaining an acceptable level of thermal and tensile performance, improving the suitability of the modified composite for engineering applications where high impact strength is critical.
MhatreAMRajaASMSaxenaS, et al.Environmentally benign and sustainable green composites: current developments and challenges. In: MuthuSS (ed). Green Composites: Sustainable Raw Materials. : Springer, pp. 53–90.
3.
HuangZZhuZZhouZ. Harmful gas reduction through synthesis of epoxy resin aqueous dispersion. Rev Compos Matér Avancés2018; 28: 529–538.
4.
DomunNHadaviniaHZhangT, et al.Improving the fracture toughness properties of epoxy using graphene nanoplatelets at low filler content. Nanocomposites2017; 3: 85–96.
5.
SarafraziMHamadanianMGhasemiAR. Optimize epoxy matrix with RSM/CCD method and influence of multi-wall carbon nanotube on mechanical properties of epoxy/polyurethane. Mech Mater2019; 138: 103154.
6.
EjazHMubasharAUddinE, et al.Effect of functionalised and non-functionalised GNPs addition on strength properties of high viscous epoxy adhesive and lap shear joints. Polym Test2022; 113: 107680.
7.
RudawskaA. Adhesives: applications and properties. BoD – Books on Demand, 2016.
8.
ThirunavukkarasuNBhuvaneswari GunasekaranHPengS, et al.Study on the interface toughening of particle/fibre reinforced epoxy composites with molecularly designed core–shell particles and various interface 3D models. Mater Des2023; 225: 111510.
9.
DineshTKadirvelAVincentA. Effect of silane modified E-glass Fibre/Iron(III)Oxide reinforcements on UP blended epoxy resin Hybrid composite. Silicon2019; 11: 2487–2498.
10.
WeiJAtifRVoT, et al.Graphene nanoplatelets in epoxy System: dispersion, reaggregation, and mechanical properties of nanocomposites. J Nanomater2015; 2015: 561742.
11.
GonçalvesFAMMSantosMCernadasT, et al.Advances in the development of biobased epoxy resins: insight into more sustainable materials and future applications. Int Mater Rev2022; 67: 119–149.
12.
VuCMNguyenDDSinhLH, et al.Improvement the mode I interlaminar fracture toughness of glass fiber reinforced phenolic resin by using epoxidized soybean oil. Polym Bull2018; 75: 4769–4782.
13.
NiedermannPSzebényiGToldyA. Effect of epoxidized soybean oil on mechanical properties of woven jute fabric reinforced aromatic and aliphatic epoxy resin composites. Polym Compos2017; 38: 884–892.
14.
BaccouchWGhithAYalcin-EnisI, et al.Enhancement of fiber-matrix interface of recycled cotton fibers reinforced epoxy composite for improved mechanical properties. Mater Res Express2020; 7: 015340.
15.
SahooSKMohantySNayakSK. Mechanical, dynamic mechanical, and interfacial properties of sisal fiber‐reinforced composite with epoxidized soybean oil‐based epoxy matrix. Polym Compos2018; 39: 2065–2072.
DevBRahmanAAlamR, et al.Mapping the progress in natural fiber reinforced composites: preparation, mechanical properties, and applications. Polym Compos2023; 44: 3748–3788.
YangJChingYCChingKY, et al.Preparation and characterization of starch-based bioplastic films modified by citric acid-epoxidized soybean oil oligomers. J Polym Environ2023; 31: 954–964.
20.
AbidiN. Introduction to FTIR microspectroscopy. FTIR Microspectroscopy. : Springer International Publishing, pp. 1–12.
21.
AhmadHRostami‐Tapeh‐EsmaeilERodrigueD. The effect of chemical crosslinking on the properties of rotomolded high density polyethylene. J Appl Polym Sci2024; 141: e54744.
22.
NikafsharSZabihiOHamidiS, et al.A renewable bio-based epoxy resin with improved mechanical performance that can compete with DGEBA. RSC Adv2017; 7: 8694–8701.
TangQChenYGaoH, et al.Bio-based epoxy resin from epoxidized soybean oil. In: KasaiM (ed). Soybean - Biomass, Yield and Productivity. IntechOpen, 2019. Epub ahead of print 20. DOI: 10.5772/intechopen.81544.
25.
WooYJKimDS. Cure and thermal decomposition kinetics of a DGEBA/amine system modified with epoxidized soybean oil. J Therm Anal Calorim2021; 144: 119–126.
26.
ThomasSBalakrishnanP (eds). Green Composites. : Springer Singapore, 2021. DOI: 10.1007/978-981-15-9643-8.
27.
CaprettiMGiammariaVSantulliC, et al.Use of bio-epoxies and their effect on the performance of polymer composites: a critical review. Polymers2023; 15: 4733.
28.
BarretoJSoaresNSouzaM, et al.Curing and degradation kinetics of crosslinked epoxidized soybean oil with isosorbide-based curing agent. J Environ Chem Eng2024; 12: 112400.
29.
PaulSMotalabMZobayerMA, et al.Strain rate and curing condition effects on the stress–strain behaviour of epoxy adhesive materials. J Adhes Sci Technol2017; 31: 1782–1795.
Di MauroCMalburetSGenuaA, et al.Sustainable series of new epoxidized vegetable oil-based thermosets with chemical recycling properties. Biomacromolecules2020; 21: 3923–3935.
34.
KarthikAJames DJDVijayanV, et al.Study on the physicomechanical, fracture-deformation, interface-adhesion, and water-absorption properties of twill fabric cotton-bamboo/epoxy composites. J Mater Res Technol2023; 24: 8429–8442.
35.
PatelRVYadavAWinczekJ. Physical, mechanical, and thermal properties of natural fiber-reinforced epoxy composites for construction and automotive applications. Appl Sci2023; 13: 5126.
36.
GuptaAPAhmadSDevA. Modification of novel bio‐based resin‐epoxidized soybean oil by conventional epoxy resin. Polym Eng Sci2011; 51: 1087–1091.
37.
ShettySSalinsSSSachidanandaHK. Design and characterization of natural fiber reinforced cotton-epoxy composites. Discov Appl Sci2024; 6: 661.
38.
IslamSHasanMBKodrićM, et al.Mechanical properties of hemp fiber‐reinforced thermoset and thermoplastic polymer composites: a comprehensive review. SPE Polym2025; 6: e10173.
39.
ShahAHLiXXuX, et al.Evaluation of mechanical and thermal properties of modified epoxy resin by using acacia catechu particles. Mater Chem Phys2019; 225: 239–246.
40.
TretyakovIVPetrovaTVKireynovAV, et al.Fracture of epoxy matrixes modified with thermo-plastic polymers and winding glass fibers reinforced plastics on their base under low-velocity impact condition. Polymers2023; 15: 2958.
41.
GraupnerNMüssigJ. A bio-inspired approach to improve the toughness of brittle bast fibre-reinforced composites using cellulose acetate foils. Biomimetics2024; 9: 131.
