Viscosity of dilute and moderately concentrated polymer solutions

Weissberg, S. G.; Simha, Robert; Rothman, Sara W.

doi:10.6028/jres.047.038

Cited by 173 publications

(49 citation statements)

References 14 publications

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“…They can only be conjectural as long as the physical significance of y is not established or suitable experimental comparisons of polymer fractions, blends, and/or whole polymer are not undertaken. The equations of the two straight lines B,C are: y (toluene) = 19.55 X lo2 an-0-640 (1) y (cyclohexane) = 2.596 X lo2 @n-0*471…”

Section: Discussionmentioning

confidence: 99%

Corresponding state relations for the viscosity of moderately concentrated polymer solutions

Utracki¹,

Simha²

1963

J. Polym. Sci. A Gen. Pap.

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SynopsisCorresponding state relationships are considered for good (toluene) and &solvents. The polymers investigated are polystyrene, polymethyl methacrylate, and a copolymer of approximately 49 mole-% of methyl methacrylate with styrene. The choice of the reduced variables q a p ( c [~] ) and c / y permits the construction of master curves, characteristic of a given polymer-solvent system over a wide range of molecular weights. The concentration parameter y varies with the degree of polymerization less rapidly than CO, the concentration for overlap of average coils, particularly in the good solvent. Here y is independent of temperature. In cyclohexane, y is proportional to the critical concentration for phase separation. The existence of such universal relations results in an explicit form for the coefficients of the power series expansions of the viscosity as a function of c. In particular the parameter kt is predicted to be a slowly decreasing function of molecular weight in the good solvent, but to be almost independent in cyclohexane. This is in accordance with recent observations for polystyrene fractions below 50,000. However, the scatter in the experimental data does not permit a quantitative comparison. Moreover, the results must be sensitive to polydispersity and depend on higher moments of the distribution, as is indicated by the relation between y and thc critical concentration.

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Section: Discussionmentioning

confidence: 99%

Corresponding state relations for the viscosity of moderately concentrated polymer solutions

Utracki¹,

Simha²

1963

J. Polym. Sci. A Gen. Pap.

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“…We propose that it is more logical to assume that ~ be constant. Analysis of poly(vinyl naphthalene)-benzene [36] and polystyrene-toluene, polystyrene-methyl ethyl ketone systems leads to similar conclusion [41].…”

Section: Viscosity-concentration Relationship: Molecular Weight Supermentioning

confidence: 55%

An AFVS model for polymer solutions: New scaling relationship

1985

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Abstract:The altered free volume state (AFVS) approach developed by Kulkarni and Mashelkar has been extended to develop a model for the viscosity of polymer solutions. The effect of polymer concentration, molecular weight and electrolyte concentration is shown to be satisfactorily explained in the framework of AFVS model. The regimes of viscosity behaviour have been defined for the systems investigated and the transitions involved identified. The approach leads to the identification of a surprisingly simple and unique scaling parameter ~p, which enables excellent concentration-molecular weight superposition.

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“…(a and b) SEM's of UHMW PA 6 fibers, stirring rate 1500 rpm tion of the material. The way in which a cluster of molecules grows to a gel and subsequently to a fiber may be derived from scanning electron micrographs (SEM) [Figures 9,10, and ll(a) and (b)]. They show fibers made at different stirring rates.…”

Section: Mechanism Of Fiber Formationmentioning

confidence: 99%

Stirring‐induced solution crystallization of ultra high molecular weight polyamide 6

Doppert

Dijk

1988

J of Applied Polymer Sci

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SynopsisUnstable solutions of ultrahigh molecular weight polyamide 6 have been prepared by adding a nonsolvent to the polymer solution. Crystallization of the polyamide from such a solution proceeds very slowly. It has been found, however, that vigorous stirring of the unstable solutions induces rapid fibrous crystallization of the polymer. The fiber mat consists of irregularly shaped fibers. A low temperature and a high stirring rate are among the conditions necessary to obtain a high yield of fibrous material. The fibers formed upon stirring have a higher molecular weight than the polyamide 6 molecules which remain in the solution. The melting point of the fibers depends on the speed of the paddle stirrer. The differential scanning calorimetry (DSC) thermogram reveals higher melting temperatures of the fibrous material if higher stirring rates have been applied.

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Viscosity of dilute and moderately concentrated polymer solutions

Cited by 173 publications

References 14 publications

Corresponding state relations for the viscosity of moderately concentrated polymer solutions

Corresponding state relations for the viscosity of moderately concentrated polymer solutions

An AFVS model for polymer solutions: New scaling relationship

Stirring‐induced solution crystallization of ultra high molecular weight polyamide 6

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