In this study, polyamide 6 and polypropylene (50/50 weight ratio) blend with 2 wt.% of single-walled carbon nanotubes was prepared by melt processing. Cryo-milling process was employed to produce the micro-sized powder form of polyamide 6. In order to evaluate the influence of polyamide 6 powder (PNPS2) on the morphology of blend, granule form of polyamide 6 (NPS2) was employed for comparison. Improvement of thermal conductivity (about 31% increase) was observed via development of fiber-like morphology of PNPS2, compared to NPS2 (co-continuous morphology). Due to small and coarse shape of polyamide 6 powder, it may hinder the coalescence of the polyamide 6 phase, resulting in the reduction of polyamide 6 nodules size, contributing to the development of fiber-like morphology. No statistical difference was found in the mechanical property of PNPS2 and NPS2. With a 60.43% of phase continuity of polyamide 6 phase in PNPS2, fiber-like morphology contributed to the increase of effective single-walled carbon nanotubes volume concentration with more filler-to-filler connection, resulting in the improvement in thermal conductivity.
TambeDESharmaMM. The effect of colloidal particles on fluid-fluid interfacial properties and emulsion stability. Adv Colloid Interfac1994; 52: 1–63.
6.
SumitaMSakataKAsaiSet al.Dispersion of fillers and the electrical conductivity of polymer blends filled with carbon black. Polym Bull1991; 25: 265–271.
7.
MaitiSShrivastavaNKKhatuaB. Reduction of percolation threshold through double percolation in melt-blended polycarbonate/acrylonitrile butadiene styrene/multiwall carbon nanotubes elastomer nanocomposites. Polym Composite2013; 34: 570–579.
8.
Otero-NavasIArjmandMSundararajU. Carbon nanotube induced double percolation in polymer blends: Morphology, rheology and broadband dielectric properties. Polymer2017; 114: 122–134.
9.
Arboleda-ClementeLGarcía-FonteXAbadM-Jet al.Role of rheology in tunning thermal conductivity of polyamide 12/polyamide 6 composites with a segregated multiwalled carbon nanotube network. J Compos Mater2018; 52: 2549–2557.
10.
LeeHYCruzHSonY. Effects of incorporation of polyester on the electrical resistivity of polycarbonate/multi-walled carbon nanotube nanocomposite. J Compos Mater2018. 0021998318801932.
11.
ZhangCYiX-SYuiHet al.Selective location and double percolation of short carbon fiber filled polymer blends: high-density polyethylene/isotactic polypropylene. Mater Lett1998; 36: 186–190.
12.
MaoCZhuYJiangW. Design of electrical conductive composites: tuning the morphology to improve the electrical properties of graphene filled immiscible polymer blends. ACS Appl Mater Interface2012; 4: 5281–5286.
13.
CaoJ-PZhaoJZhaoXet al.High thermal conductivity and high electrical resistivity of poly (vinylidene fluoride)/polystyrene blends by controlling the localization of hybrid fillers. Compos Sci Technol2013; 89: 142–148.
14.
CaoJ-PZhaoXZhaoJet al.Improved thermal conductivity and flame retardancy in polystyrene/poly (vinylidene fluoride) blends by controlling selective localization and surface modification of SiC nanoparticles. ACS Appl Mater Interface2013; 5: 6915–6924.
15.
ZhangLWanCZhangY. Morphology and electrical properties of polyamide 6/polypropylene/multi-walled carbon nanotubes composites. Compos Sci Technol2009; 69: 2212–2217.
16.
Abbasi MoudAJavadiANazockdastHet al.Effect of dispersion and selective localization of carbon nanotubes on rheology and electrical conductivity of polyamide 6 (PA6), Polypropylene (PP), and PA6/PP nanocomposites. J Polym Sci Pol Phys2015; 53: 368–378.
17.
ZhouSLuoWZouHet al.Enhanced thermal conductivity of polyamide 6/polypropylene (PA6/PP) immiscible blends with high loadings of graphite. J Compos Mater2016; 50: 327–337.
18.
KalaitzidouKFukushimaHDrzalLT. A new compounding method for exfoliated graphite–polypropylene nanocomposites with enhanced flexural properties and lower percolation threshold. Compos Sci Technol2007; 67: 2045–2051.
19.
ZhangQRastogiSChenDet al.Low percolation threshold in single-walled carbon nanotube/high density polyethylene composites prepared by melt processing technique. Carbon2006; 44: 778–785.
20.
VillmowTKretzschmarBPötschkeP. Influence of screw configuration, residence time, and specific mechanical energy in twin-screw extrusion of polycaprolactone/multi-walled carbon nanotube composites. Compos Sci Technol2010; 70: 2045–2055.
21.
PötschkePPaulD. Formation of co-continuous structures in melt-mixed immiscible polymer blends. J Macromol Sci Pol R2003; 43: 87–141.
22.
FilipponeGRomeoGAciernoD. Role of interface rheology in altering the onset of co-continuity in nanoparticle-filled polymer blends. Macromol Mater Eng2011; 296: 658–665.
23.
FenouillotFCassagnauPMajestéJ-C. Uneven distribution of nanoparticles in immiscible fluids: morphology development in polymer blends. Polymer2009; 50: 1333–1350.
KotaAKCiprianoBHDuesterbergMKet al.Electrical and rheological percolation in polystyrene/MWCNT nanocomposites. Macromolecules2007; 40: 7400–7406.
26.
VoulgarisDPetridisD. Emulsifying effect of dimethyldioctadecylammonium-hectorite in polystyrene/poly (ethyl methacrylate) blends. Polymer2002; 43: 2213–2218.
27.
Van GurpMPalmenJ. Time-temperature superposition for polymeric blends. Rheol Bull1998; 67: 5–8.
28.
YoungTIII. An essay on the cohesion of fluids. Philos Trans R Soc Lond1805; 95: 65–87.
29.
BaudouinA-CBaillyCDevauxJ. Interface localization of carbon nanotubes in blends of two copolymers. Polym Degrad Stabil2010; 95: 389–398.
30.
PötschkePPegelSClaesMet al.A novel strategy to incorporate carbon nanotubes into thermoplastic matrices. Macromol Rapid Comm2008; 29: 244–251.
31.
OwensDKWendtR. Estimation of the surface free energy of polymers. J Appl Polym Sci1969; 13: 1741–1747.
32.
FowkesFM. Attractive forces at interfaces. Indus Eng Chem1964; 56: 40–52.
33.
WuS. Calculation of interfacial tension in polymer systems. J Polym Sci C Polym Sympos1971; 34: 19–30.
34.
KirjavaJRundqvistTHolsti-MiettinenRet al.Determination of interfacial tension between PA/PP and LCP/PP by IFR method and effect of compatibilization on interfacial tension. J Appl Polym Sci1995; 55: 1069–1079.
35.
BaudouinA-CDevauxJBaillyC. Localization of carbon nanotubes at the interface in blends of polyamide and ethylene–acrylate copolymer. Polymer2010; 51: 1341–1354.
36.
PedrazzoliDPegorettiA. Expanded graphite nanoplatelets as coupling agents in glass fiber reinforced polypropylene composites. Compos Part A Appl S2014; 66: 25–34.
KhareRABhattacharyyaARKulkarniARet al.Influence of multiwall carbon nanotubes on morphology and electrical conductivity of PP/ABS blends. J Polym Sci Pol Phys2008; 46: 2286–2295.
39.
LiZ-MLiS-NXuX-Bet al.Carbon nanotubes can enhance phase dispersion in polymer blends. Polym Plast Technol Eng2007; 46: 129–134.
40.
KontopoulouMLiuYAustinJRet al.The dynamics of montmorillonite clay dispersion and morphology development in immiscible ethylene–propylene rubber/polypropylene blends. Polymer2007; 48: 4520–4528.
GanßMSatapathyBKThungaMet al.Structural interpretations of deformation and fracture behavior of polypropylene/multi-walled carbon nanotube composites. Acta Mater2008; 56: 2247–2261.
44.
ChenHGinzburgVVYangJet al.Thermal conductivity of polymer-based composites: Fundamentals and applications. Prog Polym Sci2016; 59: 41–85.
45.
BiggDElectrical properties of metal-filled polymer composites. In: BhattacharyaSK (ed). Metal-filled polymers: properties and applications, New York: Marcel Dekker, 1986, pp. 165–226.
46.
GaskaKRybakAKapustaCet al.Enhanced thermal conductivity of epoxy–matrix composites with hybrid fillers. Polym Adv Technol2015; 26: 26–31.
47.
ChoiSWYoonKHJeongS-S. Morphology and thermal conductivity of polyacrylate composites containing aluminum/multi-walled carbon nanotubes. Compos Part A Appl S2013; 45: 1–5.
48.
LeeESLeeSMShanefieldDJet al.Enhanced thermal conductivity of polymer matrix composite via high solids loading of aluminum nitride in epoxy resin. J Am Ceram Soc2008; 91: 1169–1174.
49.
LimSJLeeJGHurSHet al.Effects of MWCNT and nickel-coated carbon fiber on the electrical and morphological properties of polypropylene and polyamide 6 blends. Macromol Res2014; 22: 632–638.
