Effect of morphology on the brittle ductile transition of polymer blends: 1. A new equation for correlating morphological parameters

doi:10.1016/S0032-3861(97)00075-X

Polymer

Volume 38, Issue 21, October 1997, Pages 5267-5273

https://doi.org/10.1016/S0032-3861(97)00075-X Get rights and content

Abstract

The relationships among morphological parameters of binary polymer blends have been studied. A new equation for correlating morphological parameters: particle size (d), particle size distribution (σ), particle volume fraction (0), and matrix ligament thickness (T(d,σ,φ)) is derived. The equation is generally applicable to the binary polymer blends with the log-normal distribution of particle size and the configuration of well-dispersed particles in matrix. The effects of a and particle configuration on T(d, σ, φ) are discussed. The new equation predicts that T(d, σ, φ) increases with increasing d and o,, and with reducing φ. The effect of σ is found to be influenced by φ. The higher the φ is, the more significant the effect of σ on T(d, σ, φ) is. The new equation is applied to the poly(vinyl chloride)/nitrile rubber, polypropylene (PP)/ EPDM, and PP/EVA blends. The theoretical predictions agree well with the experimental results. The equations neglecting or underestimating the effect of σ on T(d, σ, φ), however, cause great errors. Compared with the effect of σ, the effect of particle configuration of cubic lattice assumed in deriving the new equation is much less important in the above blends. Therefore, σ is also an important morphological parameter.

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Polymer paperEffect of morphology on the brittle ductile transition of polymer blends: 1. A new equation for correlating morphological parameters

Abstract

Polymer

J. Appl. Polym. Sci.

Toughened Plastics

Fracture Behaviour of Polymers

J. Polym. Sci.

Polymer paper
Effect of morphology on the brittle ductile transition of polymer blends: 1. A new equation for correlating morphological parameters