Titanium aluminium carbide powder was reaction synthesized and used as reinforcement in the aircraft grade epoxy matrix (LY556) to develop a high-performance conductive polymer composite. The particle sizes of 4 and 7 µm were employed from 0 to 40 wt.% to improve the mechanical and electrical properties of conductive polymer composites. It was observed that the percolation characteristics were exhibited at a critical threshold of 20 wt.% for both the filler particle sizes. Further, microstructural observations revealed the formation of a conductive network in the conductive polymer composites when the filler content was 20 wt.%. The tensile and flexural properties were increased when the particle size was decreased. Experimental values were then compared with the available analytical models for validation. The mechanical and electrical properties of the conductive polymer composites were optimized by tailoring the filler particle size to 4 µm and particle loading at 20 wt.%. Compared to neat epoxy, the optimized conductive polymer composites have shown a simultaneous increase in strength, stiffness and conductivity performances, which can find applications in aerospace and electronics industries.
DangZMLinYQXuHP, et al.Fabrication and Dielectric characterization of advanced BaTiO3/polyamide nanocomposite films with high thermal stability. Adv Functl Mater2008; 18: 1509–1517.
PandaMSrinivasVThakurAK. On the question of percolation threshold in polyvinylidene fluoride/nanocrystalline nickel composites. Appl Phys Lett2008; 92: 132905–132905.
6.
LuaJMoonaKSKimbBK, et al.High dielectric constant polyaniline/epoxy composites via in situ polymerization for embedded capacitor applications. Polymer2007; 48: 1510–1516.
7.
ChenQDuPJinL, et al.Percolative conductor/Polymer composite films with significant dielectric properties. Appl Phys Lett2007; 91: 022912–022912.
8.
DeepaKSSebastianMTJamesJ. Effect of interparticle distance and interfacial area on the properties of Insulator-conductor composites. Appl Phys Lett2007; 91: 202904–202904.
9.
RaoYWongCP. Ultra high dielectric constant epoxy silver composite for embedded capacitor application. IEEE Proc Electron Comp Technol Conf2002, pp. 920–923.
10.
SuiGJanaSZhongWH, et al.Dielectric properties and conductivity of carbon nanofiber/semi-crystalline polymer composites. Acta Mater2008; 56: 2381–2388.
11.
LiQXueQZhengQ, et al.Large dielectric constant of the chemically purified carbon nanotube/polymer composites. Mater Lett2008; 62: 4229–4231.
12.
SongSHParkKHKimBH, et al.Enhanced thermal conductivity of epoxy–graphene composites by using non oxidized graphene flakes with non-covalent functionalization. Adv Mater2013; 25: 732–737.
13.
SunXSunHLiH, et al.Developing polymer composite material: carbon nanotubes or graphene. Adv Mater2013; 25: 5153–5176.
14.
ColemanJNKhanUGun’koYK. Mechanical reinforcement of polymers using carbon nanotubes. Adv Mater2006; 18: 689–706.
15.
ByrneMTGun’koYK. Recent advances in research on carbon nanotube-polymer composites. Adv Mater2010; 22: 1672–1688.
16.
HuangXZhiCJiangP, et al.Polyhedral oligosilsesquiosane modified boron nitride nanotube based epoxy nanocomposite: an dielectric material with high thermal conductivity. Adv Functl Mater2013; 23: 1824–1831.
17.
WanYJTangLCGongLX, et al.Grafting of epoxy chains onto graphene oxide for epoxy composites with improved mechanical and thermal properties. Carbon2014; 69: 467–480.
18.
GuanLZWanYJGongLX, et al.Toward effective and tunable interphase in graphene oxide/epoxy composites by grafting different chain length polyether amine onto graphene oxide. J Mater Chem2014; 2: 15058–15069.
19.
WanYJGongLXTangLC, et al.Mechanical properties of epoxy composites filled with silane-functionalized graphene oxide. Compos Part A2014; 64: 79–89.
20.
JiaJSunXLinX, et al.Exceptional electrical conductivity and fracture resistance of 3D interconnected graphene foam/epoxy composites. ACS Nano2014; 8: 5774–5783.
21.
BozlarMHeDBaiJ, et al.Carbon nanotube microarchitecture for enhanced thermal conduction at ultralow mass fraction in polymer composites. Adv Mater2010; 22: 1654–1658.
22.
SongWWangWVecaLM, et al.Polymer /carbon nanocomposites for enhanced thermal transport properties carbon tube versus graphene sheet as nanoscale fillers. J Mater Chem2012; 22: 17133–17139.
23.
HuangXZhiCZhiangP. Toward effective synergetic effect from graphene nanoplatelets and carbon nanotubes on thermal conductivity of ultrahigh volume fraction nanocarbon epoxy composites. J Phys Chem2012; 116: 23812–23820.
24.
ZhangXFanXYanC, et al.Interfacial microstructure and properties of carbon fiber composites modified with graphene oxide. ACS Appl Mater Interfaces2012; 4: 1543–1552.
25.
BekyarovaEThostensonETYuA, et al.Electronic properties of single-walled carbon nanotube networks. J Phys Chem2005; 127: 5990–5995.
26.
Gonzalez-DominguezJMAnson-CasaosADíez-PascualAM, et al.Solvent-free preparation of High toughness Epoxy- SWNT composite materials. ACS Appl Mater Interfaces2011; 3: 1441–1450.
27.
MohapatraSMantrySSinghSK. Performance evaluation of glass-epoxy-TiC hybrid composites using design of experiment. J Compos2014; 670659: 1–9.
28.
WangFZhouDGongS. Dielectric behavior of TiC–PVDF nanocomposites. Phys Status Solid RRL32009; 1: 22–24.
29.
RaptisCGPatsidisAPsarrasGC. Electrical response and functionality of polymer matrix-titanium carbide composites. eXPRESS Polym Lett2010; 4: 234–243.
KriegASKingJAJaszczakDC, et al.Tensile and conductivity properties of epoxy composites containing carbon black and graphene nano platelets. J Compos Mater2018; 52: 3909–3918.
32.
BansalSASinghAPKumarA, et al.Improved mechanical performance of bisphenol-A graphene-oxide Nano-composites. J Compos Mater2018; 52: 2179–2188.
33.
WangWJLiCWChenKP. Electrical dielectric and mechanical properties of a Novel Ti3AlC2/epoxy resin conductive composites. Mater Lett2013; 110: 61–64.
34.
VaisakhSSMaheshKVBalanandS, et al.MAX phase ternary carbide derived 2D ceramic nano structures as chemically interactive functional fillers for damage tolerant epoxy polymer nano composites. RSC Adv2015; 5: 16521–16531.
35.
GuptaSRiyadMF. Synthesis and tribological behavior of novel UHMWPE- Ti3SiC2 composites. Polym Compos2018; 39: 254–266.
36.
RadovicMBarsoumW. Bridging the gap between metals and ceramics. Am Ceram Soc Bull2013; 92: 3–20.
37.
ZhouYCWangXHSunZM, et al.Electronic and structural properties of the layered ternary carbide Ti3AlC2. J Mater Chem2001; 11: 2335–2339.
38.
TzenovNVBarsoumMW. Synthesis and characterization of Ti3AlC2. J Am Ceram Soc2000; 83: 825–832.
39.
WangXHZhouYC. Microstructure and properties of Ti3AlC2 prepared by the solid-liquid reaction synthesis and simultaneous in-situ hot pressing process. Acta Mater2002; 50: 3143–3151.
40.
OnuahoCOnyemaobiOOAnyakwoCN, et al.Effect of filler loading and particle size on the mechanical properties of periwinkle shell filled recycled polypropylene composites. Am J Eng Res2017; 4: 72–79.
41.
KundiFAzhariCHMuchtarA, et al.Effect of filler size on the mechanical properties of polymer filled dental composites: A Review of recent development. J Phys Sci2018; 29: 141–165.
42.
AbrahamRThomasSPKuryanS, et al.Mechanical properties of ceramic polymer composites. eXPRESS Polym Lett2009; 3: 177–189.
43.
FuSYFengXQLaukeB, et al.Effects of particle size, particle/matrix interface adhesion and particle loading on mechanical properties of particulate polymer composites. Compos Part B2008; 39: 933–961.
