In this review, we survey the state of the art on polymeric foams incorporating nano-scale fillers. Particular focus of the review is on foams from polyolefinic nanocomposite formulations incorporating a wide variety of fillers. The nano-scale additives can influence the foam structure and properties in two ways: Firstly, they can act as composite reinforcement to enhance the mechanical properties and functionality of the matrix polymer; and secondly, they can act as foaming-processing aids through modification of the rheological, thermal and crystallization properties of the matrix as well as serving as heterogeneous nucleation sites. Through a combination of these influences, and using advanced processing techniques it is possible to achieve nanocomposite foams that have higher cell density, and more uniform cell size or controlled cell-size distribution. Such controlled foam morphologies, in turn, can yield better specific mechanical properties resulting in more effective light-weighting solutions. Further, the nano-scale additives can impart additional desired functionality resulting in multi-functional foams. In this article, we provide an overview of the mechanical, thermal and a few other relevant functional properties – such as piezoelectric sensitivity, acoustics, and filtration efficiency – of foams prepared using nanocomposite formulations, along with the processing considerations for achieving high quality foams using such materials.
GibsonLJAshbyMF.Cellular solids. Structure and properties. Cambridge: Cambridge University Press, 1997.
2.
YonezuAHirayamaKKishidaH, et al. Characterization of the compressive deformation behavior with strain rate effect of low-density polymeric foams. Polym Test2016; 50: 1–8.
3.
PatrickCLKaewmesriWWangJ, et al. Effect of die geometry on foaming behaviors of high-melt-strength polypropylene with CO2. J Appl Polym Sci2008; 109: 3122–3132.
4.
Saiz-ArroyoCRodríguez-PérezMATiradoJ, et al. Structure-property relationships of medium-density polypropylene foams. Polym Int2013; 62: 1324–1333.
5.
OkolieochaCRapsDSubramaniamK, et al. Microcellular to nanocellular polymer foams: progress (2004–2015) and future directions – a review. Eur Polym J2015; 73: 500–519.
SerajiSMAghjehMKRDavariM, et al. Effect of clay dispersion on the cell structure of LDPE/clay nanocomposite foams. Polym Compos2011; 32: 1095–1105.
8.
AntunesMGedlerGAbbasiH, et al. Graphene nanoplatelets as a multifunctional filler for polymer foams. Materials Today Proc2016; 3: S233–S239.
9.
AntunesMGedlerGVelascoJI.Multifunctional nanocomposite foams based on polypropylene with carbon nanofillers. J Cell Plast2013; 49: 259–279.
10.
GedlerGAntunesMRealinhoV, et al. Thermal stability of polycarbonate-graphene nanocomposite foams. Polym Degrad Stab2012; 97: 1297–1304.
11.
GedlerGAntunesMBorca-TasciucT, et al. Effects of graphene concentration, relative density and cellular morphology on the thermal conductivity of polycarbonate-graphene nanocomposite foams. Eur Polym J2016; 75: 190–199.
12.
Laguna-GutierrezESaiz-ArroyoCVelascoJI, et al. Low density polyethylene/silica nanocomposite foams. Relationship between chemical composition, particle dispersion, cellular structure and physical properties. Eur Polym J2016; 81: 173–185.
13.
LobosJVelankarS.How much do nanoparticle fillers improve the modulus and strength of polymer foams?J Cell Plast2016; 52: 1–32.
14.
OkolieochaCKöpplTKerlingS, et al. Influence of graphene on the cell morphology and mechanical properties of extruded polystyrene foam. J Cell Plast2015; 51: 413–426.
15.
Saiz-ArroyoCRodríguez-PérezMÁVelascoJI, et al. Influence of foaming process on the structure-properties relationship of foamed LDPE/silica nanocomposites. Compos Part B Eng2013; 48: 40–50.
16.
ZhaiWKubokiTWangL, et al. Cell structure evolution and the crystallization behavior of polypropylene/clay nanocomposites foams blown in continuous extrusion. Ind Eng Chem Res2010; 49: 9834–9845.
17.
ZhaiWParkCBKontopoulouM.Nanosilica addition dramatically improves the cell morphology and expansion ratio of polypropylene heterophasic copolymer foams blown in continuous extrusion. Ind Eng Chem Res2011; 50: 7282–7289.
18.
LanHYTsengHC.Study on the rheological behavior of PP/supercritical CO2 mixture. J Polym Res2002; 9: 157–162.
19.
LuoYXinCZhengD, et al. Effect of processing history on the rheological properties, crystallization and foamability of branched polypropylene. J Polym Res2015; 22: 1–13.
20.
Laguna-GutierrezELopez-GilASaiz-ArroyoC, et al. Extensional rheology, cellular structure, mechanical behavior relationships in HMS PP/montmorillonite foams with similar densities. J Polym Res2016; 23: 1–16.
21.
ZhangZXGaoCXinZX, et al. Effects of extruder parameters and silica on physico-mechanical and foaming properties of PP/wood-fiber composites. Compos Part B Eng2012; 43: 2047–2057.
22.
LandrockAH (ed.) Handbook of plastic foams. New Jersey: Noyes Publications, 1995.
23.
LiuSDuvigneauJVancsoGJ.Nanocellular polymer foams as promising high performance thermal insulation materials. Eur Polym J2015; 65: 33–45.
24.
BernardoVMartín-de LeónJRodríguez-PérezMA.Production and characterization of nanocellular polyphenylsulfone foams. Mater Lett2016; 178: 155–158.
25.
LandrockAH.Handbook of plastic foams. New Jersey: Noyes Publications, 1995.
26.
XanthosMDhavalikarRTanV, et al. Properties and applications of sandwich panels based on PET foams. J Reinf Plast Compos2001; 20: 786–793.
27.
JaponSLeterrierYMånsonJ-AE.Recycling of poly(ethylene terephthalate) into closed-cell foams. Polym Eng Sci2000; 40: 1942–1952.
28.
SinghIGandhiABiswalM, et al. Multi-Stage recycling induced morphological transformations in solid-state microcellular foaming of polystyrene. Cell Polym2018; 37: 121–149.
29.
KöpplTRapsDAltstädtV.E-PBT – bead foaming of poly(butylene terephthalate) by underwater pelletizing. J Cell Plast2014; 50: 475–487.
30.
BaldwinDFParkCBSuhNP.A microcellular processing study of poly(ethylene terephthalate) in the amorphous and semicrystalline states. Part II: cell growth and process design. Polym Eng Sci1996; 36: 1437–1445.
31.
GuanRWangBLuD.Preparation of microcellular poly(ethylene terephthalate) and its properties. J Appl Polym Sci2003; 88: 1956–1962.
32.
GuanRWangBLuD, et al. Microcellular thin PET sheet foam preparation by compression molding. J Appl Polym Sci2004; 93: 1698–1704.
33.
GuanRXiangBXiaoZ, et al. The processing-structure relationships in thin microcellular PET sheet prepared by compression molding. Eur Polym J2006; 42: 1022–1032.
34.
LiangM-TWangC-M.Production of engineering plastics foams by supercritical CO2. Ind Eng Chem Res2000; 39: 4622–4626.
BaoJBNyantakyi JuniorAWengGS, et al. Tensile and impact properties of microcellular isotactic polypropylene (PP) foams obtained by supercritical carbon dioxide. J Supercrit Fluids2016; 111: 63–73.
37.
RamkumarPLKulkarniDMAbhijitVVR, et al. Investigation of melt flow index and impact strength of foamed LLDPE for rotational moulding process. Procedia Mater Sci2014; 6: 361–367.
38.
NaguibHEParkCBLeePC, et al. A study on the foaming behaviors of PP resins with talc as nucleating agent. J Polym Eng2006; 26: 565–587.
39.
AntunesMRealinhoVArdanuyM, et al. Mechanical properties and morphology of multifunctional polypropylene foams. Cell Polym2011; 30: 187–200.
40.
AntunesMVelascoJIRealinhoV.Foaming behaviour, structure, and properties of polypropylene nanocomposites foams. J Nanomater2010; 2010: 1–11.
41.
AntunesMVelascoJRealinhoV, et al. Characterization of carbon nanofibre-reinforced polypropylene foams. J Nanosci Nanotechnol2010; 10: 1241–1250.
42.
ZhengWGLeeYHParkCB.Use of nanoparticles for improving the foaming behaviors of linear PP. J Appl Polym Sci2010; 117: 2972–2979.
43.
ChaudharyAKJayaramanK.Extrusion of linear polypropylene–clay nanocomposite foams. Polym Eng Sci2011; 51: 1749–1756.
44.
NamPHMaitiPOkamotoM, et al. Foam processing and cellular structure of polypropylene/clay nanocomposites. Polym Eng Sci2002; 42: 1907–1918.
45.
OkamotoMNamPMaitiP, et al. Biaxial flow-induced alignment of silicate layers in polypropylene/clay nanocomposite foam. Nano Lett2001; 1: 503–505.
46.
WanFTranM-PLeblancC, et al. Experimental and computational micro-mechanical investigations of compressive properties of polypropylene/multi-walled carbon nanotubes nanocomposite foams. Mech Mater2015; 91: 95–118.
47.
GongWLiuKJZhangC, et al. Foaming behavior and mechanical properties of microcellular PP/SiO2 composites. Int Polym Process2012; 27: 181–186.
48.
DuttaASankarpandiSGhoshAK.Evaluation of polypropylene/clay nanocomposite foamability based on their morphological and rheological aspects. J Cell Plast2018; 54: 829–850.
49.
Laguna-GutierrezEEscuderoJRodriguez-PerezMA.Analysis of the mechanical properties and effective diffusion coefficient under static creep loading of low-density foams based on polyethylene/clays nanocomposites. Compos Part B Eng2018; 148: 156–165.
50.
LeeYHWangKHParkCB, et al. Effects of clay dispersion on the foam morphology of LDPE/clay nanocomposites. J Appl Polym Sci2007; 103: 2129–2134.
51.
KhorasaniMMGhaffarianSRBabaieA, et al. Foaming behavior and cellular structure of microcellular HDPE nanocomposites prepared by a high temperature process. J Cell Plast2010; 46: 173–190.
52.
Laguna-GutierrezEEscuderoJKumarV, et al. Microcellular foaming by using subcritical CO2 of crosslinked and non-crosslinked LDPE/clay nanocomposites. J Cell Plast2018; 54: 257–282.
NiaounakisM.Foaming and foamed products. In: Biopolymers: processing and products. 1st ed. New York: Elsevier Inc., 2015, pp.327–359.
55.
ÇengelYACimbalaJM.Fluid mechanics fundamentals and applications. New York: McGraw-Hill, 2006.
56.
WhiteFM.Fluid mechanics. 4th ed. New York: McGraw-Hill, 2010.
57.
ChenHChengM-LJeanYC, et al. Effect of CO2 exposure on free volumes in polystyrene studied by positron annihilation spectroscopy. J Polym Sci B Polym Phys2008; 46: 388–405.
58.
Lee and Scholz DieterST.Polymeric foams. Boca Raton: CRC Press, 2009.
59.
SchrammLL.Foams: fundamentals and applications in the petroleum industry. USA: American Chemical Society, 1994.
60.
JosephJ.Foams. 1st ed. New York: Springer-Verlag, 1973.
61.
MillsNJ.Polymer foams handbook: engineering and biomechanics applications and design guide. UK: Butterworth-Heinemann, 2007.
OxtobyDW.Nucleation of first-order phase transitions. Acc Chem Res1998; 31: 91–97.
64.
XiaofeiXDiegoECCosteuxS, et al. Bubble nucleation in polymer–CO2 mixtures. Soft Matter2013; 9: 9675–9683.
65.
KimYParkCBChenP, et al. Origins of the failure of classical nucleation theory for nanocellular polymer foams. Soft Matter2011; 7: 7351.
66.
ColtonJSSuhNP.The nucleation of microcellular thermoplastic foam with additives: part I: theoretical considerations. Polym Eng Sci1987; 27: 485–492.
67.
ColtonJSSuhNP.The nucleation of microcellular thermoplastic foam with additives: part II: experimental results and discussion. Polym Eng Sci1987; 27: 493–499.
68.
JungPU.Development of innovative gas-assisted foam injection molding technology. Canada: University of Toronto, 2013.
69.
ParkCBBaldwinDFSuhNP.Effect of the pressure drop rate on cell nucleation in continuous processing of microcellular polymers. Polym Eng Sci1995; 35: 432–440.
70.
ParkCBCheungLKSongS-W.The effect of talc on cell nucleation in extrusion foam processing of polypropylene with CO2 and isopentane. Cell Polym1998; 17: 221–251.
71.
AhmedMSLeeYHParkCB, et al. Effect of nanoclay on the microcellular structure and morphology of high internal phase emulsion (HIPE) foams. Asia-Pacific Jrnl of Chem Eng2009; 4: 120–124.
72.
WongAST.In situ observation of plastic foaming under static condition, extensional flow and shear flow. Canada: University of Toronto, 2012.
73.
KumarAPathamBMohantyS, et al. Polypropylene–nano-silica nanocomposite foams: mechanisms underlying foamability, and foam microstructure, crystallinity and mechanical properties. Polym Int2020; 69: 373–386.
74.
ZhaiWYuJWuL, et al. Heterogeneous nucleation uniformizing cell size distribution in microcellular nanocomposites foams. Polymer2006; 47: 7580–7589.
75.
FanCWanCGaoF, et al. Extrusion foaming of poly(ethylene terephthalate) with carbon dioxide based on rheology analysis. J Cell Plast2016; 52: 1–22.
76.
AntunesMVelascoJIRealinhoV, et al. Study of the cellular structure heterogeneity and anisotropy of polypropylene and polypropylene nanocomposite foams. Polym Eng Sci2009; 49: 2399–2413.
77.
BociagaEPalutkiewiczP.The influence of injection molding parameters and blowing agent addition on selected properties, surface state, and structure of HDPE parts. Polym Eng Sci2012; 53: 1–12.
78.
AhmadzaiABehraveshAHSarabiMT, et al. Visualization of foaming phenomena in thermoplastic injection molding process. J Cell Plast2014; 50: 279–300.
79.
NayakNCTripathyDK.Morphology and physical properties of closed cell microcellular ethylene – octene copolymer: effect of precipitated silica filler and blowing agent. J Appl Polym Sci2002; 83: 357–366.
80.
KumarAPathamBMohantyS, et al. Effect of temperature on thermal, mechanical and morphological properties of polypropylene foams prepared by single step and two step batch foaming process. J Polym Res2019; 26: 1–14.
AntunesMRealinhoVSolórzanoE, et al. Thermal conductivity of carbon nanofibre-polypropylene composite foams. Defect Diffus Forum2010; 297–301: 996–1001.
83.
Moscoso-SanchezFJMendizabalEJasso-GastinelCF, et al. Morphological and mechanical characterization of foamed polyethylene via biaxial rotational molding. J Cell Plast2015; 51: 489–503.
84.
ChenLOzisikRSchadlerLS.The influence of carbon nanotube aspect ratio on the foam morphology of MWNT/PMMA nanocomposite foams. Polymer2010; 51: 2368–2375.
85.
ZhaiWYuJHeJ.Ultrasonic irradiation enhanced cell nucleation: an effective approach to microcellular foams of both high cell density and expansion ratio. Polymer2008; 49: 2430–2434.
86.
GandhiAAsijaNKumar GaurK, et al. Ultrasound assisted cyclic solid-state foaming for fabricating ultra-low density porous acrylonitrile-butadiene-styrene foams. Mater Lett2013; 94: 76–78.
87.
GandhiAAsijaNChauhanH, et al. Ultrasound-Induced nucleation in microcellular polymers. J Appl Polym Sci2014; 133: 1–5.
88.
FathiAAltstädtV.Mechanical properties of multifunctional foam core materials. 1st ed. USA: William Andrew, 2015.
89.
ColliasDIBairdDG.Impact behavior of microcellular foams of polystyrene and styrene-acrylonitrile copolymer, and single-edge-notched tensile toughness of microcellular foams of polystyrene, styrene-acrylonitrile copolymer, and polycarbonate. Polym Eng Sci1995; 35: 1178–1183.
90.
de VriesDVWM.Characterization of polymeric foams. Eindhoven: Eindhoven University of Technology, 2009.
91.
ChristensenRM.Mechanics of low density materials. J Mech Phys Solids1986; 34: 563–578.
92.
AntunesMRealinhoVVelascoJI.Study of the influence of the pressure drop rate on the foaming behavior and dynamic-mechanical properties of CO2 dissolution microcellular polypropylene foams. J Cell Plast2010; 46: 551–571.
93.
ShenJHanXLeeLJ.Nanoscaled reinforcement of polystyrene foams using carbon nanofibers. J Cell Plast2006; 42: 105–126.
94.
ZimmermannMVPaola da SilvaMZatteraAJ, et al. Poly(lactic acid) foams reinforced with cellulose micro and nanofibers and foamed by chemical blowing agents. J Cell Plast2018; 54: 1–20.
95.
RizviRKimJ-KNaguibH.Synthesis and characterization of novel low density polyethylene–multiwall carbon nanotube porous composites. Smart Mater Struct2009; 18: 104002–104010.
ChenLSchadlerLSOzisikR.An experimental and theoretical investigation of the compressive properties of multi-walled carbon nanotube/poly (methyl methacrylate) nanocomposite foams. Polymer2011; 52: 2899–2909.
98.
JoCNaguibHE.Effect of nanoclay and foaming conditions on the mechanical properties of HDPE–clay nanocomposite foams. J Cell Plast2007; 43: 111–121.
99.
GhasemiIFarshehATMasoomZ.Effects of multi-walled carbon nanotube functionalization on the morphological and mechanical properties of nanocomposite foams based on poly(vinyl chloride)/(wood flour)/(multi-walled carbon nanotubes). J Vinyl Addit Technol2012; 18: 161–167.
100.
Shin HwangSHsuPPYehJM, et al. Effect of clay and compatibilizer on the mechanical/thermal properties of microcellular injection molded low density polyethylene nanocomposites. Int Commun Heat Mass Transf2009; 36: 471–479.
101.
MechraouiARiedlBRodrigueD.Mechanical properties of polypropylene structural foams with fiber-reinforced skins. J Cell Plast2011; 47: 115–132.
102.
MrlíkMAl Ali Al MaadeedM.Tailoring of the thermal, mechanical and dielectric properties of the polypropylene foams using gamma-irradiation. Polym Degrad Stab2016; 133: 234–242.
103.
AlmanzaORodríguez-PérezMAde SajaJA.Measurement of the thermal diffusivity and specific heat capacity of polyethylene foams using the transient plane source technique. Polym Int2004; 53: 2038–2044.
104.
PalutkiewiczPPostawaP.The investigation of selected properties of the porous moulded parts from talc-filled PP composites. J Cell Plast2016; 52: 399–418.
105.
WuJChuH.Heat transfer in open cell polyurethane foam insulation. Heat Mass Transf1998; 34: 247–254.
106.
KumarPTopinFVicenteJ.Determination of effective thermal conductivity from geometrical properties: application to open cell foams. Int J Therm Sci2014; 81: 13–28.
107.
AntunesMVelascoJIRealinhoV, et al. Heat transfer in polypropylene-based foams produced using different foaming processes. Adv Eng Mater2009; 11: 811–817.
108.
KalaprasadGPradeepPMathewG, et al. Thermal conductivity and thermal diffusivity analyses of low-density polyethylene composites reinforced with sisal, glass and intimately mixed sisal/glass fibres. Compos Sci Technol2000; 60: 2967–2977.
109.
TavmanHI.Effective thermal conductivity of isotropic polymer composites. Int Commun Heat Mass Transf1998; 25: 723–732.
110.
DingHLeungSN.Modelling of effective thermal conductivity of polymer matrix composite foams with biaxially aligned filler networks. J Cell Plast2016; 52: 1–18.
111.
VignolesGLOrtonaA.Numerical study of effective heat conductivities of foams by coupled conduction and radiation. Int J Therm Sci2016; 109: 270–278.
112.
DoermannDDSacaduraJF.Heat transfer in open cell foam insulation. J. Heat Transfer1996; 118: 88–93.
113.
SchuetzMAGlicksmanLR.A basic study of heat transfer through foam insulation. J Cell Plast1984; 20: 114–121.
114.
ScheutzMA.Heat transfer in foam insulation. Cambridge, MA: Massachusetts Institute of Technology, 1982.
115.
MorenoJD.Radiative transfer and thermal performance levels in foam insulation boardstocks. Cambridge, MA: Massachussetts Institute of Technology, 1991.
116.
GlicksmanLRTorpeyMMargeA.Means to improve the thermal conductivity of foam insulation. J Cell Plast1992; 28: 571–583.
117.
FerklPPokornýRBobákM, et al. Heat transfer in one-dimensional micro- and nano-cellular foams. Chem Eng Sci2013; 97: 50–58.
118.
MillerDKumarV.Microcellular and nanocellular solid-state polyetherimide (PEI) foams using Sub-critical carbon dioxide II. Tensile and impact properties. Polymer2011; 52: 2910–2919.
119.
WeiGLiuYZhangX, et al. Thermal conductivities study on silica aerogel and its composite insulation materials. Int J Heat Mass Transf2011; 54: 2355–2366.
120.
ShiAZhangGZhaoC.Study of rigid cross-linked pvc foams with heat resistance. Molecules2012; 17: 14858–14869.
121.
SavaciUYilmazSGüdenM.Open cell lead foams: processing, microstructure, and mechanical properties. J Mater Sci2012; 47: 5646–5654.
GeisslerBFeuchterMLaskeS, et al. Strategies to improve the mechanical properties of high-density polylactic acid foams. J Cell Plast2014; 52: 15–35.
124.
ZhaoJZhaoQWangC, et al. High thermal insulation and compressive strength polypropylene foams fabricated by high-pressure foam injection molding and mold opening of nano-fibrillar composites. Mater Des2017; 131: 1–11.
125.
BarusSZanettiMLazzariM, et al. Preparation of polymeric hybrid nanocomposites based on PE and nanosilica. Polymer2009; 50: 2595–2600.
126.
SongPCaoZCaiY, et al. Fabrication of exfoliated graphene-based polypropylene nanocomposites with enhanced mechanical and thermal properties. Polymer2011; 52: 4001–4010.
127.
RealinhoVHaurieLAntunesM, et al. Thermal stability and fire behaviour of flame retardant high density rigid foams based on hydromagnesite-filled polypropylene composites. Compos Part B Eng2014; 58: 553–558.
128.
LiuHDongMHuangW, et al. Lightweight conductive graphene/thermoplastic polyurethane foams with ultrahigh compressibility for piezoresistive sensing. J Mater Chem C2017; 5: 73–83.
129.
LeeSZhuLMaiaJ.The effect of strain-hardening on the morphology and mechanical and dielectric properties of multi-layered PP foam/PP film. Polymer2015; 70: 173–182.
130.
QinYPengQDingY, et al. Light-weight, super-elastic and mechanically flexible graphene/polyimide nanocomposite foam for strain sensor application. ACS Nano2015; 9: 8933–8941.
131.
ZhaoXChenBWeiG, et al. Polyimide/graphene nanocomposite foam-based wind-driven triboelectric nanogenerator for self-powered pressure sensor. Adv Mater Technol2019; 4: 1800723–1800729.
132.
ZuruziASHaffizTMAffidahD, et al. Towards wearable pressure sensors using multiwall carbon nanotube/polydimethylsiloxane nanocomposite foams. Mater Des2017; 132: 449–458.
133.
BirdEMerrellJRosquistP, et al. Effect of environmental and material factors on the response of nanocomposite foam impact sensors. Smart Mater Struct2018; 27.
134.
HaoBMuLMaQ, et al. Stretchable and compressible strain sensor based on carbon nanotube foam/polymer nanocomposites with three-dimensional networks. Compos Sci Technol2018; 163: 162–170.
135.
ZhaoTZhangDYuC, et al. Facile fabrication of a polyethylene mesh for oil/water separation in complex environment. ACS Appl Mater Interfaces2016; 8: 24186–24191.
136.
PatilCSPatilVRAnbhuleSN, et al. Waste packaging polymeric foam for oil-water separation: an environmental remediation. Data Brief2018; 19: 86–92.
137.
LiJYanLTangX, et al. Robust superhydrophobic fabric bag filled with polyurethane sponges used for vacuum-assisted continuous and ultrafast absorption and collection of oils from water. Adv Mater Interfaces2016; 3: 1500770–1500778.
138.
XuZXuePZhuF, et al. Effects of formulations and processing parameters on foam morphologies in the direct extrusion foaming of polypropylene using a single-screw extruder. J Cell Plast2005; 41: 169–185.
139.
OkamotoMNamPHMaitiP, et al. A house of cards structure in polypropylene/clay nanocomposites under elongational flow. Nano Lett2001; 1: 295–298.
140.
YuanWWangFChenZ, et al. Efficient grafting of polypropylene onto silica nanoparticles and the properties of PP/PP-g-SiO2 nanocomposites. Polymer2018; 151: 242–249.
141.
IshiharaSHikimaYOhshimaM.Preparation of open microcellular polylactic acid foams with a microfibrillar additive using coreback foam injection molding processes. J Cell Plast2018; 54: 1–20.
142.
LeeSHZhangYKontopoulouM, et al. Optimization of dispersion of nanosilica particles in a PP matrix and their effect on foaming. Int Polym Process2011; 26: 388–398.
143.
WuHZhaoGWangJ, et al. Effects of process parameters on core-back foam injection molding process. eXPRESS Polym Lett2019; 13: 390–405.
144.
WuHZhaoGWangG, et al. A new core-back foam injection molding method with chemical blowing agents. Mater Des2018; 144: 331–342.
145.
WangLOkadaKHikimaY, et al. Effect of cellulose nanofiber (CNF) surface treatment on cellular structures and mechanical properties of polypropylene/CNF nanocomposite foams via Core-Back foam injection molding. Polymers (Basel)2019; 11: 249.
146.
MengLWuDKellyA, et al. Geometry dependence of the elongation behavior of a polypropylene melt through a micro die. Polym Test2017; 59: 185–192.
147.
GomezJFDavidASanchez-SotoM, et al. Influence of the injection moulding parameters on the microstructure and thermal properties of microcellular polyethylene terephthalate glycol foams. J Cell Plast2012; 49: 47–63.
148.
KotzevGDjoumaliiskySKrastevaM, et al. Effect of sample configuration on the morphology of foamed LDPE/PP blends injection molded by a gas counterpressure process. Macromol Mater Eng2007; 292: 769–779.
149.
Tovar-CisnerosCGonzález-NúñezRRodrigueD.Effect of mold temperature on morphology and mechanical properties of injection molded HDPE structural foams. J Cell Plast2008; 44: 223–237.
150.
Demori1RBischoffEde AzeredoAP, et al. Morphological, thermo-mechanical, and thermal conductivity properties of halloysite nanotube-filled polypropylene nanocomposite foam. J Cell Plast2018; 54: 1–17.
151.
MarkLHChuRKMWangGL, et al. High-pressure preform foam blow molding. Int Polym Process2017; 32: 637–647.
152.
PintoJEscuderoJSolórzanoE, et al. A novel route to produce structural polymer foams with a controlled solid skin-porous core structure based on gas diffusion mechanisms. J Sandw Struct Mater2020; 22: 1–11.
153.
YusaAYamamotoSGotoH, et al. A new microcellular foam injection-molding technology using non-supercritical fluid physical blowing agents. Polym Eng Sci2017; 57: 105–113.
154.
BarzegariMRRodrigueD.The effect of injection molding conditions on the morphology of polymer structural foams. Polym Eng Sci2009; 49: 949–959.
