Influence of molecular weight distribution on the linear viscoelastic properties of polymer blends

Han, Chang Dae

doi:10.1002/app.1988.070350115

Cited by 81 publications

(44 citation statements)

References 49 publications

(35 reference statements)

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“…In other words, the two normal stress differences of ( 11 Ϫ 22 ) and ( 11 Ϫ 33 ) were almost identical, and the normal stress difference ( 11 Ϫ 33 ) was proportional to the square root of 12 . Thus, their results were consistent with a linear viscoelastic theory such as the Maxwell model in which the plot of ( 11 Ϫ 33 ) versus 12 gives rise to the slope of factor 2 in log-log scale as the Cole-Cole plot of GЈ vs GЉ (44,45). Consequently, ͗n 11 Ϫ n 33 ͘ is proportional to the square root of 12 and n 12 ϰ ͌ |͗n 11 Ϫ n 33 ͘| for a linear viscoelastic material.…”

Section: Correlation Of the Stress Optical Rulesupporting

confidence: 77%

Rheo-optical Behaviors and Stability of a Silica Particle Suspension Coated with Silane Coupling Agents

Lee

Yang

1998

Journal of Colloid and Interface Science

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Section: Correlation Of the Stress Optical Rulesupporting

confidence: 77%

Rheo-optical Behaviors and Stability of a Silica Particle Suspension Coated with Silane Coupling Agents

Lee

Yang

1998

Journal of Colloid and Interface Science

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“…All the data measured at various temperatures and molecular weights can be described by a single master curve in the log(G 0 ) versus log(G 00 ) plot. [23] Experimental investigations have also shown that the SCB would not affect the master curve. However, any change in chain topology, such as LCBing, and PDI would lead to a significant deviation of data points from the master curve.…”

Section: Time-temperature Superposition and Flow Activation Energymentioning

confidence: 99%

“…However, any change in chain topology, such as LCBing, and PDI would lead to a significant deviation of data points from the master curve. [4b] In the terminal region, theoretical derivations [23] have shown that, for monodisperse linear polymers with M > M e ,…”

Section: Time-temperature Superposition and Flow Activation Energymentioning

confidence: 99%

Melt Rheological Properties of Branched Polyethylenes Produced with Pd‐ and Ni–Diimine Catalysts

AlObaidi

Zhu

2004

Macro Chemistry & Physics

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Summary: Seven branched polyethylenes differing in chain topology from hyperbranched to linear structure were synthesized with chain walking Pd‐diimine catalyst, [(ArNC(Me)C(Me)NAr) Pd(CH3)(NCMe)]SbF6 (1), and Ni‐diimine catalyst, (ArNC(An)C(An)NAr) NiBr2 (2)/MMAO, respectively. An extensive rheological study, employing steady‐shear, creep‐recovery, and dynamic oscillation tests, was conducted to examine and compare the melt rheological properties of this novel series of polymers. It was found that the change of chain topology dramatically affected the polymer flow behavior, flow activation energy, and dynamic moduli (G′(ω), G″(ω)). The hyperbranched polymers exhibited typical Newtonian flow behavior and extremely low viscosity. The polymers with chain topology intermediate between hyperbranched and linear structures, however, were essentially viscoelastic materials. All the polymers obeyed the time‐temperature superposition and exhibited enhanced flow activation energy (43.8∼57.2 kJ/mol) compared to HDPE and LLDPE. In the terminal region, these polymers had different dependencies of dynamic moduli (G′(ω), G″(ω)) on angular frequency (ω) and different master curves in the log(G′) versus log(G″) plot. The hyperbranched polymer was also blended with more linear samples as a rheology modifier and was found to significantly lower the viscosity of the blends.Structure of the Pd‐ and Ni‐catalysts used in this study.imageStructure of the Pd‐ and Ni‐catalysts used in this study.

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“…G′(ω) at high frequencies reduced with BE fraction, since highly deformed BE particles acted as a role of plasticizer. Moreover, the relationship between the storage modulus (G′) and the loss modulus (G″) (Han plot) can be used to characterize the miscibility of polymer blends [51,52]. The Han plot of PLA/BE blends is displayed in Fig.…”

Section: Rheological Propertiesmentioning

confidence: 99%

Employing a novel bioelastomer to toughen polylactide

Kang

Qiao

Wang

et al. 2013

Polymer

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ABSTRACT. Biodegradable, biocompatible polylactide (PLA) synthesized from renewable resources has attracted extensive interests over the past decades and holds great potential to replace many petroleum-derived plastics. With no loss of biodegradability and biocompatibility, we highly toughened PLA using a novel bioelastomer (BE)-synthesized from biomass diols and diacids. Although PLA and BE are immiscible, BE particles of ~1 µm in diameter are uniformly dispersed in the matrix, and this indicates some compatibility between PLA and BE. BE significantly increased the cold crystallization ability of PLA, which was valuable for practical processing and performance. SEM micrographs of fracture surface showed a brittle-to-ductile transition owing to addition of BE. At 11.5 vol%, notched Izod impact strength improved from 2.4 to 10.3 kJ/m 2 , 330% increment; the increase is superior to previous toughening effect by using petroleum-based tougheners.

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Influence of molecular weight distribution on the linear viscoelastic properties of polymer blends

Cited by 81 publications

References 49 publications

Rheo-optical Behaviors and Stability of a Silica Particle Suspension Coated with Silane Coupling Agents

Rheo-optical Behaviors and Stability of a Silica Particle Suspension Coated with Silane Coupling Agents

Melt Rheological Properties of Branched Polyethylenes Produced with Pd‐ and Ni–Diimine Catalysts

Employing a novel bioelastomer to toughen polylactide

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