“…First, a plasticizer effect of the ABS-g-MAH was prepared by a reactive extrusion and might have residual reactants and chains that suffered thermo-oxidative degradation. 31 Second, a better dispersion of the ABS phase into the CB, was observed in our previous work. 31 For the nanocomposites, the rheological results at lowfrequency regions (0.02 to 5 rad/s) are in accordance with the mechanical, electrical, and morphological properties observed in the fractographic analysis and could be associated with the GNP dispersion and the morphology of the nanocomposites.…”
Section: Rheological Behavior and Correlation With Morphology Of The Nanocompositessupporting
confidence: 55%
“…31 Second, a better dispersion of the ABS phase into the CB, was observed in our previous work. 31 For the nanocomposites, the rheological results at lowfrequency regions (0.02 to 5 rad/s) are in accordance with the mechanical, electrical, and morphological properties observed in the fractographic analysis and could be associated with the GNP dispersion and the morphology of the nanocomposites. The composition NG3, unlike the others, presented a decrease on the η* value when compared to NB, as an effect of an expressive reduction on the storage modulus (G 0 ).…”
Section: Rheological Behavior and Correlation With Morphology Of The Nanocompositessupporting
confidence: 55%
“…The details of the chosen composition and other characterizations are disposable in our previous work. 31 Graphene nanoplates (GNP) were supplied by Cheaptubes (USA) with 97% of purity, average thickness of 8-15 nm, lateral size dimension >2 μm, and specific surface area of 500-700 m 2 /g. The GNP was produced by chemical exfoliation of natural graphite.…”
Section: Methodsmentioning
confidence: 99%
“…The maleic anhydride grafted ABS (ABS‐ g ‐MAH) with MFI of 7.1 ± 0.05 g/10 min (230°C/3.8 kg) and with 0.7 ± 0.08 wt% of grafted MAH was utilized as a compatibilizer agent and was produced by reactive processing in lab scale using a benzoyl peroxide (BPO) and maleic anhydride (MAH) system. The details of the chosen composition and other characterizations are disposable in our previous work 31 …”
Section: Methodsmentioning
confidence: 99%
“…The appearance of a new band at 1780 cm À1 in ABS-g-MAH indicates that the reactive extrusion was effectively performed. 16,17,31,49,50 In both spectra, ABS characteristic bands were observed at 2238 cm À1 (related to C N bonds), at 1494 and 1602 cm À1 (related to carbon atoms bonded to a benzene ring in styrene), and at 911 and 966 cm À1 (related to polybutadiene structures). 16,49…”
Section: Spectroscopic Characterizations (Gnp and Abs-g-mah)mentioning
Polymeric blends based on polycarbonate (PC) and acrylonitrile-styrenebutadiene copolymer (ABS) are applied mainly in the electronic and automotive industries. Studies to improve the properties of PC/ABS blend have led to graphene nanoplates (GNP) addition, a carbon nanofiller derived from graphite that presents some of the promising properties of graphene. In this work, the effect of the addition of GNP (3 and 5 wt%) and maleic anhydride grafted ABS (ABS-g-MAH) were evaluated on the thermal, mechanical, rheological, and electromagnetic properties of PC/ABS blends (85/15), a different blend ratio of previous studies. It was verified that the GNP addition significantly increased the thermal stability of the blends. Furthermore, the mechanical tests showed that ABS-g-MAH acted as an efficient compatibilizer for the PC/ABS blends, and the GNP addition improved the Shore D hardness, the elastic modulus, and the maximum tensile strength of all compositions.Besides, it was observed an overlapping effect of the GNP and ABS-g-MAH addition on the mechanical properties of the blend. The addition of 3 wt% GNP to the PC/ABS (85/15) blend also doubled the elongation at break of the material. Furthermore, these contents resulted in a slight increase of the electromagnetic waves attenuation of 1-2 dB associated to electromagnetic waves reflection.
“…First, a plasticizer effect of the ABS-g-MAH was prepared by a reactive extrusion and might have residual reactants and chains that suffered thermo-oxidative degradation. 31 Second, a better dispersion of the ABS phase into the CB, was observed in our previous work. 31 For the nanocomposites, the rheological results at lowfrequency regions (0.02 to 5 rad/s) are in accordance with the mechanical, electrical, and morphological properties observed in the fractographic analysis and could be associated with the GNP dispersion and the morphology of the nanocomposites.…”
Section: Rheological Behavior and Correlation With Morphology Of The Nanocompositessupporting
confidence: 55%
“…31 Second, a better dispersion of the ABS phase into the CB, was observed in our previous work. 31 For the nanocomposites, the rheological results at lowfrequency regions (0.02 to 5 rad/s) are in accordance with the mechanical, electrical, and morphological properties observed in the fractographic analysis and could be associated with the GNP dispersion and the morphology of the nanocomposites. The composition NG3, unlike the others, presented a decrease on the η* value when compared to NB, as an effect of an expressive reduction on the storage modulus (G 0 ).…”
Section: Rheological Behavior and Correlation With Morphology Of The Nanocompositessupporting
confidence: 55%
“…The details of the chosen composition and other characterizations are disposable in our previous work. 31 Graphene nanoplates (GNP) were supplied by Cheaptubes (USA) with 97% of purity, average thickness of 8-15 nm, lateral size dimension >2 μm, and specific surface area of 500-700 m 2 /g. The GNP was produced by chemical exfoliation of natural graphite.…”
Section: Methodsmentioning
confidence: 99%
“…The maleic anhydride grafted ABS (ABS‐ g ‐MAH) with MFI of 7.1 ± 0.05 g/10 min (230°C/3.8 kg) and with 0.7 ± 0.08 wt% of grafted MAH was utilized as a compatibilizer agent and was produced by reactive processing in lab scale using a benzoyl peroxide (BPO) and maleic anhydride (MAH) system. The details of the chosen composition and other characterizations are disposable in our previous work 31 …”
Section: Methodsmentioning
confidence: 99%
“…The appearance of a new band at 1780 cm À1 in ABS-g-MAH indicates that the reactive extrusion was effectively performed. 16,17,31,49,50 In both spectra, ABS characteristic bands were observed at 2238 cm À1 (related to C N bonds), at 1494 and 1602 cm À1 (related to carbon atoms bonded to a benzene ring in styrene), and at 911 and 966 cm À1 (related to polybutadiene structures). 16,49…”
Section: Spectroscopic Characterizations (Gnp and Abs-g-mah)mentioning
Polymeric blends based on polycarbonate (PC) and acrylonitrile-styrenebutadiene copolymer (ABS) are applied mainly in the electronic and automotive industries. Studies to improve the properties of PC/ABS blend have led to graphene nanoplates (GNP) addition, a carbon nanofiller derived from graphite that presents some of the promising properties of graphene. In this work, the effect of the addition of GNP (3 and 5 wt%) and maleic anhydride grafted ABS (ABS-g-MAH) were evaluated on the thermal, mechanical, rheological, and electromagnetic properties of PC/ABS blends (85/15), a different blend ratio of previous studies. It was verified that the GNP addition significantly increased the thermal stability of the blends. Furthermore, the mechanical tests showed that ABS-g-MAH acted as an efficient compatibilizer for the PC/ABS blends, and the GNP addition improved the Shore D hardness, the elastic modulus, and the maximum tensile strength of all compositions.Besides, it was observed an overlapping effect of the GNP and ABS-g-MAH addition on the mechanical properties of the blend. The addition of 3 wt% GNP to the PC/ABS (85/15) blend also doubled the elongation at break of the material. Furthermore, these contents resulted in a slight increase of the electromagnetic waves attenuation of 1-2 dB associated to electromagnetic waves reflection.
Characterizing and understanding composite polymeric systems' rheological behavior is essential to tune their melt flow in polymer processing machinery. Also, rheological tests are suitable tools to evaluate the microstructure and interface adhesion of polymeric composites, which are relevant parameters on the composite performance in their applications. Poly(acrylonitrile‐co‐butadiene‐co‐styrene) (ABS) and its composites are essential materials used to manufacture consumer goods necessary to maintain the quality of life of human beings. In this work, we report on polymer systems based on ABS and poly(styrene‐block‐ethylene‐co‐butylene‐block‐styrene)‐graft‐maleic anhydride (SEBS‐g‐MA) as polymer matrix containing dispersed copper microparticles (ABS:SEBS‐g‐MA:Cu). Polydopamine, a bioinspired polymer, was applied as a filler‐matrix interface compatibilizer of the composites. The linear viscoelastic rheological measurements evidence a shear‐thinning behavior for the composites, and the polydopamine coating affects the polymer phase's relaxation time. The cohesive energy density (Ec) and SEM micrographs indicate good adhesion between copper and ABS:SEBS‐g‐MA due to polydopamine interfacial adherence.
Polycarbonate (PC)/acrylonitrile‐butadiene‐styrene copolymer (ABS) blend‐based multi‐wall carbon nanotubes (MWCNT) nanocomposites is an attractive alternative for the manufacture of electronics housing as it can have the mechanical and electromagnetic properties required for this application. The preferred location of MWCNT in PC/ABS blend is an important parameter to obtain better mechanical and electromagnetic properties. In this way, three different blending protocols (BP) were used to obtain PC/ABS/maleic anhydride‐grafted ABS (ABS‐g‐MAH) (85/10/5) blend‐based MWCNT nanocomposites with the addition of 0.5 and 1 wt% of MWCNT in a twin‐screw extruder. Specimens were evaluated by thermal (thermogravimetric analysis—TGA and differential scanning calorimetry—DSC), mechanical (Izod impact strength and tensile tests), dynamic mechanical analysis (DMA), electrical, and rheological properties, which were correlated with the nanocomposites morphology evaluated by high‐resolution scanning electron microscopy. The BP associated with the addition of a compatibilizer agent influenced the MWCNT distribution and location in the polymeric matrix. The one‐step extrusion process results in MWCNT mostly at the interface of the PC/ABS blend and agglomerates, leading to lower mechanical and thermal properties. The BP in which a PC/MWCNT masterbatch was first prepared and then diluted in ABS and ABS‐g‐MAH achieves the higher mechanical properties, increasing Young's modulus and the ultimate tensile strength. The third BP in which MWCNT was added in a second step in the blend already processed resulted in a homogeneous dispersion of MWCNT on both phases and a lower electrical resistivity.
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