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Van Gurp–Palmen relations for long-chain branching from general rigid bead-rod theory

M. A. Kanso, A. Jeffrey Giacomin

2020Physics of Fluids22 citationsDOIOpen Access PDF

Abstract

Empirically, we find that parametric plots of mechanical loss angle vs complex shear modulus may depend neither on temperature [M. van Gurp and J. Palmen, “Time-temperature superposition for polymeric blends,” Rheol. Bull. 67, 5–8 (1998)] nor on average molecular weight [S. Hatzikiriakos, “Long chain branching and polydispersity effects on the rheological properties of polyethylenes,” Polym. Eng. Sci. 40, 2279 (2000)]. Moreover, Hatzikiriakos (2000) discovered that, for fixed polydispersity, these van Gurp–Palmen curves descend with long-chain branching content. In this paper, we find that general rigid bead-rod theory [O. Hassager, “Kinetic theory and rheology of bead-rod models for macromolecular solutions. II. Linear unsteady flow properties,” J. Chem. Phys. 60(10), 4001–4008 (1974)] can explain these descents. We explore the effects of branching along a straight chain in small-amplitude oscillatory shear flow. Specifically, we explore the number of branches, branch length, branch position, and branch distribution.

Topics & Concepts

Branching (polymer chemistry)RheologyDispersityPhysicsShear flowViscoelasticityThermodynamicsChain (unit)PolymerMechanicsPolymer chemistryMaterials scienceComposite materialNuclear magnetic resonanceAstronomyRheology and Fluid Dynamics StudiesBlood properties and coagulationPolymer crystallization and properties
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