Rubber-Modified Glassy Amorphous Polymers Prepared via Chemically Induced Phase Separation. 1. Morphology Development and Mechanical Properties

Jansen, Bjp Bernard; Rastogi, Sanjay; Meijer, Heh Han; Lemstra, PJ Piet

doi:10.1021/ma001809z

Cited by 57 publications

(45 citation statements)

References 35 publications

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“…This was inspired by synchrotron experiments on a similar system, PMMAaliphatic epoxy blends with extremely small structures in the order of 30 nm. [56][57][58][59] Under low speed testing ductile behavior was found since the material was able to initiate voids within the rubbery domain prior to shear yielding. Under high loading rates, realized by notching the sample, the material behaved brittle and no cavitation occurred.…”

Section: Results Of Analyses Of Improved Microstructuresmentioning

confidence: 99%

Multi‐Scale Analysis of Mechanical Properties of Amorphous Polymer Systems

Meijer

Govaert

2003

Macro Chemistry & Physics

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Use of proper constitutive equations for the intrinsic behavior of glassy polymers (including yield, strain softening and hardening) allows nowadays for analyzing the mechanical response of homogeneous and heterogeneous polymer systems in great detail. Analyses are performed on both the periodic RVE, representative volume element, level and, via a MLFEM, multi‐level finite element method, also on the macroscopic level of e.g. a notched, scratched tensile test bar. Introduction of a failure criterion, in this case the critical tri‐axial stress that initiates crazing, allows for the prediction of brittle‐to‐tough transitions, both as a function of temperature as well as of the absolute critical local material thickness. The analyses give clear suggestions towards possible directions to optimize the microstructure in heterogeneous polymer systems in order to obtain the ultimate toughness of polymers.

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Section: Results Of Analyses Of Improved Microstructuresmentioning

confidence: 99%

Multi‐Scale Analysis of Mechanical Properties of Amorphous Polymer Systems

Meijer

Govaert

2003

Macro Chemistry & Physics

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“…The incorporation of precavitated, adhering core-shell rubbers, as proposed by Refs. [17,30], could support these ligaments during deformation to transfer more load. As a result they would be able to induce sequential yielding throughout the RVE, increase the material volume participating in the deformation and hence further improve the toughness.…”

Section: Discussionmentioning

confidence: 99%

“…Experimental results provided by Van der Sanden [28] and Jansen [30] showed that a BDT occurs in non-adhering core-shell rubber filled polystyrene at 55 vol.% inclusions of 200 nm and 35 vol.% inclusions of 80 nm, respectively. In Jansen's example a critical inter-particle distance of 11.5 nm is found.…”

Section: Bdt Induced By Length-scale Effectsmentioning

confidence: 99%

Prediction of brittle-to-ductile transitions in polystyrene

Melick

Govaert

Meijer

2003

Polymer

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In this study it is attempted to predict brittle-to-ductile transitions (BDTs) in polystyrene blends, induced either by an increase in temperature or by a decrease in inter-particle distance. A representative, two-dimensional volume element (RVE) of a polystyrene matrix with 20% circular voids, is deformed in tension. During deformation a hydrostatic-stress based craze-nucleation criterion [1] is evaluated. The simulations demonstrate that crazes initiate at low temperatures while a transition from crazing to shear yielding (BDT) is found around 75 8C. The numerical results correlate well with tensile tests on similar heterogeneous polystyrene. The presence of an absolute length, as experimentally found, is more difficult to explain. Near a free surface a T g -depression is measured for polystyrene and also the resistance to indentation in polystyrene is lower than expected from bulk properties. Both observations are rationalised by an enhanced segmental mobility of chains near a free surface. As a consequence of these findings, an absolute length-scale could be incorporated in the numerical simulations. For simplicity, the length-scale is modelled by taking a temperature gradient over a thin layer near the internal free surfaces of the RVE. Deformation of the RVE with different absolute length-scales shows that indeed also the experimentally found brittle-to-ductile transition can be predicted if the ligament thickness between the inclusions ('voids') in polystyrene is below a critical value of ca. 15 nm.

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“…17 PMMA have been toughened successfully by incorporating rubber particles. 18 They achieved superior toughness values with the average particle size of 50 nm in 70:30 PMMA/rubber blend. Blends of PMMA with polyethylene terephthalate (PET) was studied by Kamata et al, 19 and their results shows good processability and high impact strength.…”

Section: Introductionmentioning

confidence: 91%

Investigation on thermoplastic co‐poly(ether‐ester) elastomer toughened poly(methylmethacrylate) blends

Poomalai

Varghese

Siddaramaiah³

2008

J of Applied Polymer Sci

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Blends of poly(methyl methacrylate) (PMMA) and copoly(ether-ester) (COPE) elastomer have been prepared in different compositions namely, 95/5, 90/10, 85/15, and 80/20 wt % (PMMA/COPE), by melt mixing technique using twin screw extruder. The influence of COPE content on the mechanical properties especially impact strength, thermal behavior, and chemical resistance of PMMA have been investigated. The impact strength of the PMMA/COPE blends for all the compositions were found to be improved remarkably as compared to the virgin PMMA without affecting the other mechanical properties significantly. Various composite models, such as series model, parallel model, Halpin-Tsai equation, and Kerner's model have been used to fit the experimental mechanical properties. The effect of chemical and thermal ageing on the performance of the PMMA/COPE blends was also studied.

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Rubber-Modified Glassy Amorphous Polymers Prepared via Chemically Induced Phase Separation. 1. Morphology Development and Mechanical Properties

Cited by 57 publications

References 35 publications

Multi‐Scale Analysis of Mechanical Properties of Amorphous Polymer Systems

Multi‐Scale Analysis of Mechanical Properties of Amorphous Polymer Systems

Prediction of brittle-to-ductile transitions in polystyrene

Investigation on thermoplastic co‐poly(ether‐ester) elastomer toughened poly(methylmethacrylate) blends

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