Rheology and Tube Model Theory of Bimodal Blends of Star Polymer Melts

Blottière, Benoît; McLeish, Tom; Hakiki, A.; Young, R. N.; Milner, Scott T.

doi:10.1021/ma980093t

Cited by 43 publications

(50 citation statements)

References 16 publications

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“…As the formalism is applicable to star polymer melts with arbitrary arm-length polydispersity we have shown that for a monodisperse distribution it reduces to that of the original PFTM, while for a bimodal distribution we recover the theory of Blottière et al [10] for bimodal star blends. For the particular case of a Flory distribution, we could derive analytical expressions for both the universal relaxation potential U(z), Equation (46), and the concentration of unrelaxed material c(z), Equation (47).…”

Section: Resultssupporting

confidence: 55%

“…This expression is a generalization, applicable to arbitrary molecular weight distributions (see Appendix A), of expressions (17) and (18) in the paper by Blottière et al [10] on bimodal blends of star polymers. Because there one has w(m) :…”

Section: Polydisperse Extension Of the Pftmmentioning

confidence: 99%

“…For star polymer melts, it is in particular the effect of polydispersity in the molecular weight of the arms that one is looking for. This problem has been considered both experimentally and theoretically by Blottière et al [10] for the special case of a bimodal blend of two monodisperse star polymers sharing the same chemistry. Their extension of the PFTM is clearly able to quantitatively describe the great diversity in rheological behavior one encounters for these blends, and without additional parameters is able to qualitatively account for relaxation times and entire relaxation functions varying over many orders of magnitude with degree of blending.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Rheology of Polydisperse Star Polymer Melts: Extension of the Parameter‐Free Tube Model of Milner and McLeish to Arbitrary Arm‐Length Polydispersity

Slot

Steeman

2005

Macro Theory & Simulations

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Summary: This paper considers the extension of the parameter‐free tube model of Milner and McLeish for stress relaxation in melts of monodisperse star polymers to star polymers whose arms have a continuous molecular weight distribution such as the Flory distribution in the case of star‐nylons and star‐polyesters. Exact expressions are derived for the relaxation spectrum and the relaxation modulus for star polymers having an arbitrary continuous arm‐length distribution. For a Flory distribution a comparison is made with results of dynamic measurements on a melt of 8‐arm poly(ε‐caprolactone) (PCL) stars. An excellent quantitative agreement over a large frequency range is found, however, only if one treats, in contrast with the original parameter‐free tube model approach, the entanglement molecular weight that determines the relaxation spectrum as a fitting parameter independent of the entanglement molecular weight of the linear PCL. This discrepancy is not in anyway related to the polydispersity in arm‐length, but a consequence of the thermorheological complexity of the PCL stars. A similar discrepancy has been observed for hydrogenated polybutadiene stars, as described by Levine and Milner.Measured and calculated storage moduli G′ as a function of frequency ω.magnified imageMeasured and calculated storage moduli G′ as a function of frequency ω.

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Section: Resultssupporting

confidence: 55%

Section: Polydisperse Extension Of the Pftmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Rheology of Polydisperse Star Polymer Melts: Extension of the Parameter‐Free Tube Model of Milner and McLeish to Arbitrary Arm‐Length Polydispersity

Slot

Steeman

2005

Macro Theory & Simulations

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“…Predictions of the resulting theory for G ¤ …! † and data from [277] are given in ®gure 33, together with a comparison spectrum of a linear monodisperse PI. Both the relaxation times and the detailed forms of the response function clearly vary exponentially with the relative fraction of the two components, yet the two-parameter theory captures the complete behaviour.…”

Section: Tube Theory Of Entangled Polymer Dynamicsmentioning

confidence: 99%

Tube theory of entangled polymer dynamics

McLeish

2002

Advances in Physics

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838

1,122

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The dynamics of entangled¯exible polymers is dominated by physics general to many chemical systems. It is an appealing interdisciplinary ®eld where experimental and theoretical physics can work closely with chemistry and chemical engineering. The role of topological interactions is particularly important, and has given rise to a successful theoretical framework: the`tube model'. Progress over the last 30 years is reviewed in the light of specially-synthesized model materials, an increasing palette of experimental techniques, simulation and both linear and nonlinear rheological response. Our current understanding of a series of processes in entangled dynamics:`reptation',`contour length¯uctuation' and`constraintrelease' are set in the context of remaining serious challenges. Especial attention is paid to the phenomena associated with polymers of complex topology or`long chain branching'.

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“…This explains why many recent studies [3,[16][17][18][19] have been devoted to the prediction of LVE for ideal model molecules, mainly monodisperse stars, H-shaped or POM-POM molecules and combs. Some studies on simple mixtures of star architectures [20] or mixtures of stars with linear chains [21,22] or asymmetric stars [23] have been published also. For the analysis of more complex structures, two main molecular approaches have been proposed.…”

Section: Introductionmentioning

confidence: 99%