Polymer-based nanocomposites have been broadly investigated to improve its specific properties such as thermal and mechanical properties to use in different application areas. In this study, we aimed to ameliorate the desired physical properties of polyvinyl butyral (PVB) by introducing various amounts of silver (Ag) and cobalt (Co) nanoparticles (NPs) in the polymer matrix. The arc-discharge method submerged in liquid nitrogen was performed to synthesize the metal NPs. To produce hybrid nanocomposites, we demonstrated embedding Ag:Co nanoparticles in the PVB matrix via easy/low-cost solution casting process without any additional materials. In the results of analysis for nanocomposites, it was observed that there were improvements in thermal, mechanical and microwave absorption characteristics of the PVB polymer with interaction of NPs with the polymer. As a result of these interactions, the hybridization of PVB with the metal NPs resulted in the improved thermal stability since the glass transition temperature was increased from 45.6 to 55.1 °C. Besides, while the tensile strength (σ) of the bare PVB film was calculated as 20.52 MPa, the strength of the corresponding tensile strength (σ) of 1.0 wt.% Ag:Co nanocomposite film was improved to 43.41 MPa. Moreover, in order to determine the effect of these changes on the radar absorption feature of nanocomposites, one-dimensional A-Scan measurements were performed on 2–18 GHz frequency band. In the results, it was observed that 1.0%.wt Ag:Co nanocomposite film absorbed approximately 90% of the incoming energy. The characterization results revealed that a positive synergetic effect raised in the case of the modification of the PVB matrix with both Ag and Co NPs. In the light of these data, it was understood that the characteristics of PVB were improved with the NPs combining, and the usage area of that will also increase thanks to this improvement. These regenerated properties made the hybrid nanocomposite a promising substrate material with considerable potential applications for various transparent, flexible, and portable surface coatings.
de MenezesLRCavalcanteMDVazJDMR, et al. Obtention of higher refractive index and transparent polymeric nanocomposite systems with small amounts of fillers for lenses application. J Compos Mater2021; 55: 675–686.
2.
AmangahMSalami-KalajahiMRoghani-MamaqaniH.Nanoconfinement effect of graphene on thermophysical properties and crystallinity of matrix-grafted graphene/crosslinked polysulfide polymer nanocomposites. Diam Relat Mater2018; 83: 177–183.
3.
XueDWangWPiaoLH, et al. PVA-co-PE nanofibers synergistically reinforced composite film with high transparency and flexibility. Compos Commun2020; 20: 100371.
4.
ZanjanijamARHakimS.AziziH.Effect of morphology development on the crystallization behavior, dynamic mechanical properties, and toughness of the PA-6/plasticized PVB/organoclay nanocomposites. Polym Compos2019; 40: E242–E254.
5.
FernandezMDFernandezMJHocesP.Synthesis of poly(vinyl butyral)s in homogeneous phase and their thermal properties. J Appl Polym Sci2006; 102: 5007–5017.
6.
HoepfnerJCLoosMRPezzinSH.Evaluation of thermomechanical properties of polyvinyl butyral nanocomposites reinforced with graphene nanoplatelets synthesized by in situ polymerization. J Appl Polym Sci2018; 135: 46157.
7.
IpakchiHRezadoustAMEsfandehM, et al. Modeling and optimization of electrospinning conditions of PVB nanofiber by RSM and PSO-LSSVM models for improved interlaminar fracture toughness of laminated composites. J Compos Mater2020; 54: 363–378.
8.
ZhangXHHaoHShiYC, et al. The mechanical properties of polyvinyl butyral (PVB) at high strain rates. Constr Build Mater2015; 93: 404–415.
9.
XuJLiYBGeDY, et al. Experimental investigation on constitutive behavior of PVB under impact loading. Int J Impact Eng2011; 38: 106–114.
10.
TupyMMerinskaDKasparkovaV. PVB sheet recycling and degradation. In: Material recycling – trends and perspectives (ed. Dimitris Achilias) 2012, pp.133–150.
11.
AkinayYHayatF.Synthesis and microwave absorption enhancement of BaTiO3 nanoparticle/polyvinylbutyral composites. J Compos Mater2019; 53: 593–601.
12.
ChenJJGaoXH.Thermal and electrical anisotropy of polymer matrix composite materials reinforced with graphene nanoplatelets and aluminum-based particles. Diam Relat Mater2019; 100: 107571.
13.
YildizKGurkanITurgutF, et al. Fracture toughness enhancement of fuzzy CNT-glass fiber reinforced composites with a combined reinforcing strategy. Compos Commun2020; 21: 100423.
14.
NaphonPWiriyasartSNaphonN.Thermal, mechanical, and electrical properties of rubber latex with TiO2 nanoparticles. Compos Commun2020; 22: 100449.
15.
ZanjanijamARHajianMKoohmarehGA.Fabrication of single wall carbon Nanotubes-Based poly(vinyl butyral) nanocomposites with enhanced mechanical and thermal properties. J Macromol Sci A2014; 51: 369–377.
16.
SaravananSGuptaSRamamurthyPC, et al. Effect of silane functionalized alumina on poly(vinyl butyral) nanocomposite films: thermal, mechanical, and moisture barrier studies. Polym Compos2014; 35: 1426–1435.
17.
BoraPJAzeemIVinoyKJ, et al. Morphology controllable microwave absorption property of polyvinylbutyral (PVB)-MnO2 nanocomposites. Compos Part B-Eng2018; 132: 188–196.
18.
HouYFXuYLiHP, et al. Polyvinyl butyral/modified SiO2 nanoparticle membrane for gasoline desulfurization by pervaporation. Chem Eng Technol2019; 42: 65–72.
19.
KirchbergSRudolphMZiegmannG, et al. Nanocomposites based on technical polymers and sterically functionalized soft magnetic magnetite nanoparticles: synthesis, processing, and characterization. J Nanomater2012; 2012: 1–8.
20.
JiangYLShiXJFengYZ, et al. Enhanced thermal conductivity and ideal dielectric properties of epoxy composites containing polymer modified hexagonal boron nitride. Compos Part A-Appl S2018; 107: 657–664.
21.
MondalSDasPGangulyS, et al. Thermal-air ageing treatment on mechanical, electrical, and electromagnetic interference shielding properties of lightweight carbon nanotube based polymer nanocomposites. Compos part A-Appl S2018; 107: 447–460.
22.
ChoiHJLimJYZhangK.Poly(methyl methacrylate)/multi-walled carbon nanotube microbead composites via dispersion polymerization under ultrasonication. Diam Relat Mater2008; 17: 1498–1501.
23.
YoungRJLiuMFKinlochIA, et al. The mechanics of reinforcement of polymers by graphene nanoplatelets. Compos Sci Technol2018; 154: 110–116.
24.
AbudabbusMMJevremovicINesovicK, et al. In situ electrochemical synthesis of silver-doped poly(vinyl alcohol)/graphene composite hydrogels and their physico-chemical and thermal properties. Compos Part B-Eng2018; 140: 99–107.
25.
XinFLiL.Decoration of carbon nanotubes with silver nanoparticles for advanced CNT/polymer nanocomposites. Compos Part A-Appl S2011; 42: 961–967.
26.
LiuYChengPGuoQH, et al. Ag nanoparticles decorated PVA-co-PE nanofibrous microfiltration membrane with antifouling surface for efficient sterilization. Compos Commun2020; 21: 100379.
27.
LiuTPangYZhuM, et al. Microporous Co@CoO nanoparticles with superior microwave absorption properties. Nanoscale2014; 6: 2447–2454.
28.
WenFSZhangFLiuZY.Investigation on microwave absorption properties for multiwalled carbon nanotubes/Fe/Co/Ni nanopowders as lightweight absorbers. J Phys Chem C2011; 115: 14025–14030.
29.
JamkhandePGGhuleNWBamerAH, et al. Metal nanoparticles synthesis: an overview on methods of preparation, advantages and disadvantages, and applications. J Drug Deliv Sci Tec2019; 53: 101174.
30.
DasRShahnavazZAliME, et al. Can we optimize arc discharge and laser ablation for Well-Controlled carbon nanotube synthesis?Nanoscale Res Lett2016; 11: 1–23.
31.
IijimaS.Helical microtubules of graphitic carbon. Nature1991; 354: 56–58.
32.
AvciAEskizeybekVGulceH, et al. ZnO-TiO2 nanocomposites formed under submerged DC arc discharge: preparation, characterization and photocatalytic properties. Appl Phys A2014; 116: 1119–1125.
33.
EskizeybekVDemirOAvciA, et al. Synthesis and characterization of cadmium hydroxide nanowires by arc discharge method in de-ionized water. J Nanopart Res2011; 13: 4673–4680.
34.
ZhangHQZouGSLiuL, et al. A comparative study of silver nanoparticles synthesized by arc discharge and femtosecond laser ablation in aqueous solution. Appl Phys a-Mater2016; 122: 1–14.
35.
AlipourRKhorshidiAShojaeiAF, et al. Skin wound healing acceleration by Ag nanoparticles embedded in PVA/PVP/pectin/mafenide acetate composite nanofibers. Polym Test2019; 79: 106022.
36.
ChaJJunGHParkJK, et al. Improvement of modulus, strength and fracture toughness of CNT/epoxy nanocomposites through the functionalization of carbon nanotubes. Compos Part B-Eng2017; 129: 169–179.
37.
BanerjeeMSachdevPMukherjeeGS.Preparation of PVA/Co/Ag film and evaluation of its magnetic and microstructural properties. J Appl Phys2012; 111: 094302.
38.
KunduSJayachandranM.Shape-selective synthesis of non-micellar cobalt oxide (CoO) nanomaterials by microwave irradiations. J Nanopart Res2013; 15: 1543.
39.
SharmaSNirkheCPethkarS, et al. Chloroform vapour sensor based on copper/polyaniline nanocomposite. Sensor Actuat B-Chem2002; 85: 131–136.
40.
MiWBGuoLJiangEY, et al. Structure and magnetic properties of facing-target sputtered Co-C granular films. J Phys D: Appl Phys2003; 36: 2393–2399.
41.
AshkarranAAA.Novel method for synthesis of colloidal silver nanoparticles by arc discharge in liquid. Curr Appl Phys2010; 10: 1442–1447.
42.
LinYXZhuCQAlvaG, et al. Palmitic acid/polyvinyl butyral/expanded graphite composites as form-stable phase change materials for solar thermal energy storage. Appl Energ2018; 228: 1801–1809.
43.
ChoCHChoMSSungJH, et al. Preparation and characterization of poly(vinyl butyral)/Na+-montmorillonite nanocomposite. J Mater Sci2004; 39: 3151–3153.
44.
ChangJHAnYUChoDH, et al. Poly(lactic acid) nanocomposites: comparison of their properties with montmorillonite and synthetic mica(II). Polymer2003; 44: 3715–3720.
45.
BharadwajRKMehrabiARHamiltonC, et al. Structure-property relationships in cross-linked polyester-clay nanocomposites. Polymer2002; 43: 3699–3705.
46.
BikiarisD.Can nanoparticles really enhance thermal stability of polymers? Part II: an overview on thermal decomposition of polycondensation polymers. Thermochim Acta2011; 523: 25–45.
47.
ChrissafisKAntoniadisGParaskevopoulosKM, et al. Comparative study of the effect of different nanoparticles on the mechanical properties and thermal degradation mechanism of in situ prepared poly(E-caprolactone) nanocomposites. Compos Sci Technol2007; 67: 2165–2174.
48.
TripathyARMacKnightWJ.Poly(butylene terephthalate) nanocomposites prepared by in-situ polymerization. Abstr Pap Am Chem S2004; 227: U558. U558.
49.
PapageorgiouDGTerzopoulouZFinaA, et al. Enhanced thermal and fire retardancy properties of polypropylene reinforced with a hybrid graphene/glass-fibre filler. Compos Sci Technol2018; 156: 95–102.
50.
TangHBSuYCTanJ, et al. Optical properties and thermal stability of poly(vinyl butyral) films embedded with LaB6@SiO2 core-shell nanoparticles. Superlattice Microst2014; 75: 908–915.
51.
DhaliwalAKHayJN.The characterization of polyvinyl butyral by thermal analysis. Thermochim Acta2002; 391: 245–255.
52.
BlattmannCOPratsinisSE.Nanoparticle filler content and shape in polymer nanocomposites. Kona Powder Kona2019; 36: 3–32.
53.
MollaSCompanV.Nanocomposite SPEEK-based membranes for direct methanol fuel cells at intermediate temperatures. J Membrane Sci2015; 492: 123–136.
54.
TeeBCKWangCAllenR, et al. An electrically and mechanically self-healing composite with pressure- and flexion-sensitive properties for electronic skin applications. Nature Nanotech2012; 7: 825–832.
55.
HooperPABlackmanBRKDearJP.The mechanical behaviour of poly(vinyl butyral) at different strain magnitudes and strain rates. J Mater Sci2012; 47: 3564–3576.
56.
LiangCBSongPGuHB, et al. Nanopolydopamine coupled fluorescent nanozinc oxide reinforced epoxy nanocomposites. Compos Part a-Appl S2017; 102: 126–136.
57.
ZhangYChoiJRParkSJ.Thermal conductivity and thermo-physical properties of nanodiamond-attached exfoliated hexagonal boron nitride/epoxy nanocomposites for microelectronics. Compos Part A-Appl S2017; 101: 227–236.
58.
ObradovicVStojanovicDBZivkovicI, et al. Dynamic mechanical and impact properties of composites reinforced with carbon nanotubes. Fiber Polym2015; 16: 138–145.
59.
PizzanelliSForteCBroncoS, et al. PVB/ATO nanocomposites for glass coating applications: effects of nanoparticles on the PVB matrix. Coatings2019; 9: 247.
60.
AkinayYHayatFColakB.Absorbing properties and structural design of PVB/Fe3O4 nanocomposite. Mater Chem Phys2019; 229: 460–466.
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