Insight into the crystalline morphology,thermal phase transitions and static,dynamic mechanical response of polypropylene hybrid composites reinforced with nanosilica and glass fibres
Restricted accessResearch articleFirst published online March, 2026
Insight into the crystalline morphology,thermal phase transitions and static,dynamic mechanical response of polypropylene hybrid composites reinforced with nanosilica and glass fibres
The present study focuses on investigating the effects of glass fibre and nanosilica, both individually and in combination, in polypropylene matrix. The hybrid multiscale composite specimens are prepared by fixing the composition of glass fibre at 20 wt.% and the weight percentage of nanosilica was varied by 2, 4 and 6. The resultant composite was characterised by scanning electron microscopy, dynamic mechanical analysis, tensile and fracture toughness tests, thermogravimetric analysis and differential scanning calorimetry (DSC). The hybrid composite with 2 wt.% nanosilica demonstrated the greatest stiffness and better ability to bear loads and absorb energy, indicating improved mechanical performance. The improvement in storage modulus and loss factor can be attributed to the addition of nanosilica into the polypropylene/glass fibre (PPG) matrix, indicating the synergism of the two multiscale fillers involved. The hybrid samples at higher content of nanosilica (6 wt%) exhibited the highest shift in thermal decomposition temperatures, thereby referring to prominent thermal stability. The thermal analysis performed via DSC analysis revealed the nucleating ability of nanosilica, and the accelerated nucleation of PP phase owing to the dual effect of fillers which have enhanced the crystallinity.
MaddahHA. Polypropylene as a promising plastic: a review. Am J Polym Sci2016; 6: 1–11.
2.
MaierCCalafutT. Polypropylene: the definitive user's guide and databook. Norwich, New York: William Andrew, 1998.
3.
WangWZhangWLiangB. The influences of multiple factors for flexural performance of polypropylene: crystallization, crystal evolution, nanoparticles.J Mater Sci2021; 56: 15667–15683.
4.
SilvaFNjugunaJSachseS, et al.The influence of multiscale fillers reinforcement into impact resistance and energy absorption properties of polyamide 6 and polypropylene nanocomposite structures. Mater Des2013; 50: 244–252.
5.
WatanabeRSugaharaAHagiharaH, et al.Insight into interfacial compatibilization of glass-fiber-reinforced polypropylene (PP) using maleic-anhydride modified PP employing infrared spectroscopic imaging. Compos Sci Technol2020; 199: 108379.
6.
CabanR. Examinations of structure and properties of polymer composite with glass fiber.Compos Theory Pract2019; 4: 150–156.
7.
SoitongTPumchusakJ. The relationship of crystallization behavior, mechanical properties, and morphology of polypropylene nanocomposite fibers. J Mater Sci2011; 46: 1697–1704.
8.
SutarHMishraBSenapatiP, et al.Mechanical, thermal, and morphological properties of graphene nanoplatelet-reinforced polypropylene nanocomposites: effects of nanofiller thickness. J Compos Sci2021; 5: 24.
9.
CuiYHWangXXLiZQ, et al.Fabrication and properties of nano-ZnO/glass-fiber-reinforced polypropylene composites. J Vinyl Addit Technol2010; 16(3): 189–194.
10.
WuCLZhangMQRongMZ, et al.Tensile performance improvement of low nanoparticles filled-polypropylene composites. Compos Sci Technol2002; 62: 1327–1340.
11.
LinOHAkilHMMohd IshakZA. Surface-activated nanosilica treated with silane coupling agents/polypropylene composites: mechanical, morphological, and thermal studies. Polym Compos2011; 32(10): 1568–1583.
12.
SutarHMishraBSenapatiP, et al.Mechanical, thermal, and morphological properties of graphene nanoplatelet-reinforced polypropylene nanocomposites: effects of nanofiller thickness. J Compos Sci2021; 5: 24.
13.
JeniferARasanaNJayanarayananK. Synergistic effect of the inclusion of glass fibers and halloysite nanotubes on the static and dynamic mechanical, thermal and flame- retardant properties of polypropylene.Mater Res Exp2018; 5: 065308.
PedrazzoliDPegorettiAKalaitzidouK. Synergistic effect of graphite nanoplatelets and glass fibers in polypropylene composites. J Appl Polym Sci2015; 12: 132.
16.
RasanaNMalavikaDAparnaR, et al.Influence of multiphase fillers on mechanical, transport and rheological properties of polypropylene. Mater Today Proc2018; 5: 16478–16486.
17.
AwadSAKhalafEM. Investigation of improvement of properties of polypropylene modified by nano silica composites. Compos Commun2019; 12: 59–63.
18.
KimJKimD. Compatibilizing effects of maleic anhydride-grafted-polypropylene (PP) on long carbon fiber-reinforced PP composites. J Thermoplast Compos Mater2014; 28: 1599–1611.
19.
ManafiPGhasemiIKarrabiM, et al.Effect of graphene nanoplatelets on crystallization kinetics of poly (lactic acid). Soft Mater2014; 12: 433–444.
20.
JacobSSumaKKMendazJM, et al.Modification of polypropylene/glass fiber composites with nanosilica. Macromol Symp2009; 277: 138–143.
21.
LeeSKimD-HParkJ-H, et al.Effect of curing poly (p-phenylene sulfide) on thermal properties and crystalline morphologies. Macromolecules2015; 184: 145–149.
22.
ArencónDVelascoJI. Fracture toughness of polypropylene-based particulate composites. Materials2009; 2: 2046–2094.
23.
PrasadMSVenkateshaCSJayarajuT. Experimental methods of determining fracture toughness of fiber reinforced polymer composites under various loading conditions. J Min Mater Characterizat Eng2011; 10: 1263.
24.
RasanaNJayanarayananK. Experimental and micromechanical modeling of fracture toughness: MWCNT-reinforced polypropylene/glass fiber hybrid composites. J Thermoplast Compos Mater2019; 32: 1031–1055.
25.
GharzouliNDoufnouneRRiahiF, et al.Effects of nanosilica filler surface modification and compatibilization on the mechanical, thermal and microstructure of PP/EPR blends. J Adhes Sci Technol2019; 33: 445–467.
26.
JosephPVMathewGJosephK, et al.Dynamic mechanical properties of short sisal fibre reinforced polypropylene composites. Compos A: Appl Sci Manuf2003; 34: 275–290.
27.
AraoYYumitoriSSuzukiH, et al.Mechanical properties of injection-molded carbon fiber/polypropylene composites hybridized with nanofillers. Compos A: Appl Sci Manuf2013; 55: 19–26.
28.
YooYSpencerMWPaulDR. Morphology and mechanical properties of glass fiber reinforced Nylon 6 nanocomposites. Polymer2011; 52: 180–190.
29.
KaganjABRashidiAMArastehR, et al.Crystallisation behaviour and morphological characteristics of poly (propylene)/multi-walled carbon nanotube nanocomposites. J Exp Nanosci2009; 4: 21–34.
30.
ZhouTHRuanWHMaiYL, et al.Performance improvement of nano-silica/polypropylene composites through in-situ cross-linking approach. Compos Sci Technol2008; 68(14): 2858–2863.
31.
AminM. Methods for preparation of nano-composites for outdoor insulation applications. Rev Adv Mater Sci2013; 34: 173–184.
32.
SintoJGeorgeKE. Modification of Short Fibre Reinforced pp and HDPE Using Nanosilica (Doctoral dissertation, Cochin University of Science & Technology), 2009.
33.
SushantaKSSmitaMSanjayKN. Polypropylene—bamboo/glass fiber hybrid composites: fabrication and analysis of mechanical, morphological, thermal, and dynamic mechanical behavior. J Reinf Plast Compos2008; 28: 2729–2747.
34.
SeoMKLeeJRParkSJ. Crystallization kinetics and interfacial behaviors of polypropylene composites reinforced with multi-walled carbon nanotubes. Mater Sci Eng: A2005; 404: 79–84.
35.
JyotiJSinghBPAryaAK, et al.Dynamic mechanical properties of multiwall carbon nanotube reinforce ABS composites and their correlation with entanglement density, adhesion, reinforcement and C factor. RSC Adv2016; 6: 3997–4006.
36.
SabaNJawaidMAlothmanOY, et al.A review on dynamic mechanical properties of natural fibre reinforced polymer composites. Constr Build Mater2016; 106: 149–159.
37.
FuSYMaiYWLaukeB, et al.Synergistic effect on the fracture toughness of hybrid short glass fiber and short carbon fiber reinforced polypropylene composites. Mater Sci Eng A2002; 323: 326–335.
38.
BalakrishnanPSreekalaMSKunaverM, et al.Morphology, transport characteristics and viscoelastic polymer chain confinement in nanocomposites based on thermoplastic potato starch and cellulose nanofibers from pineapple leaf. Carbohydr Polym2017; 169: 176–188.
39.
TaraghiIFereidoonAZamaniMM, et al.Mechanical, thermal, and viscoelastic properties of polypropylene/glass hybrid composites reinforced with multiwalled carbon nanotubes. J Compos Mater2015; 49: 3557–3566.
40.
RahmanNAHassanAYahyaR, et al.Polypropylene/glass fiber/nanoclay hybrid composites: morphological, thermal, dynamic mechanical and impact behaviors. J Reinf Plast Compos2012; 31: 1247–1257.
41.
KarsliNGAytacA. Effects of maleated polypropylene on the morphology, thermal and mechanical properties of short carbon fiber reinforced polypropylene composites. Mater Des2011; 32: 4069–4073.
42.
InuwaIMArjmandiRIbrahimAN, et al.Enhanced mechanical and thermal properties of hybrid graphene nanoplatelets/multiwall carbon nanotubes reinforced polyethylene terephthalate nanocomposites. Fibers Polym2016; 17: 1657–1666.
43.
RaghvanSSinghalPRattanS, et al.Durable PP/EPDM/GF/SiO2 nanocomposites with improved strength and toughness for orthotic applications. J Mech Behav Biomed Mater2023; 1: 105582.
44.
UzayÇ. Investigation of physical, mechanical, and thermal properties of glass fiber reinforced polymer composites strengthened with KH550 and KH570 silane-coated silicon dioxide nanoparticles. J Compos Mater2022; 56: 2995–3011.
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