Masters Theses

Date of Award

5-1995

Degree Type

Thesis

Degree Name

Master of Science

Major

Polymer Engineering

Major Professor

Paul J. Phillips

Committee Members

J. E. Spruiell, R. S. Benson

Abstract

The correct value of the equilibrium melting point of isotactic polypropylene has been determined using small angle x-ray diffraction. The conflict in the literature between the two very different values obtained through extrapolation of melting point versus crystallization temperature data has been resolved. It is demonstrated through studies of the melting point of polypropylene as a function of crystallization time that the dependence of melting point elevation on supercooling is the opposite of that of polyethylene. The thickening process is shown to be most effective at low supercoolings leading to abnormally high melting points for specimens crystallized at low supercoolings. The equilibrium melting point of isotactic polypropylene is close to 186°C. It is believed that the observed behavior is a direct result of polypropylene crystallizing in Regimes II and III, unlike bulk linear polyethylene which crystallizes in Regimes I and II. It is suggested that the behavior may be directly related to the length of continuous adjacent reentry folding generated under the different regimes.

The crystallization behavior of high molecular weight deuterated polypropylene has been studied using hot stage optical microscopy and differential scanning calorimetry. It is found that the equilibrium melting point is 8.3 to 8.9°C below that of polypropylene, correlating well with a theoretical estimate of 8.7°C. The polymer shows a Regime II - Regime III transition, as does polypropylene, but the transition temperatures of both polymers are close to one another and unrelated to supercooling. It is suggested that this is a result of the Regime II Regime III transition - being controlled by molecular mobility factors, unlike a Regime I - Regime II transition temperature, which is controlled by supercooling. Values of fold surface free energy of deuterated polypropylene were found to approximately 60% of those of polypropylene.

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