Crystallization and melting behavior of an aromatic semicrystalline polyimide, LaRC CPI-2

Brandom, Donald Keith

03 October 2007

Research is presented on the crystallization and melting behavior of an aromatic semi crystalline polyimide known as LaRC CPI - 2 (Langley Research Center Crystalline rolyimide - second generation). This aromatic polyimide, a structural variant of the well known LaRC CPI, is synthesized froml 1,4-bis( 4-aminophenoxy-4' -benzoyl)benzene (1,4-BABB) and 4,4' -oxydiphthalic dianhydride (ODPA). The multiple melting behavior at ca. 334°C and 364°C, characteristic of this polymer, is analyzed and explained. Transmission electron microscopy (TEM), wide angle X-ray diffraction (W AXD), and small angle X-ray scattering (SAXS) studies, in conjunction with differential scanning calorimetry (DSC) analysis, show that the high melting transition results from the melting of lamellae which were melt recrystallized during heating in a DSC. The effects of synthesis and process variables upon the crystallization and melting properties of this polyimide were also studied. The DSC response of LaRC CPI - 2 films and powders of varying molecular weight are compared and contrasted. Powders generally melt at a higher temperature than films of the same molecular weight. The glass transition temperature, T g' of both the powders and films are found to be dependent upon molecular weight. An interpolated value of T g for the infinite molecular weight LaRC CPI - 2 is ca. 234°e. In a study of the development of crystallinity in films during standard thermal imidization, crystallinity was found to initiate off the glass surface very early in the process leaving an amorphous layer at the air surface after the full thermal treatment. LaRC CPI - 2 powder 'types' synthesized in different solvents, dimethylacetamide (DMAc) and m-cresol present with dramatically different melting, melt stability and crystallization properties. Though the chemical architecture and crystal lattice structure are the same, the powders synthesized in DMAc display dual melting transitions at ca. 334°C and 364°C, while the powders from m-cresol melt singularly at ca. 409°C. Rheological analysis, along with annealing data, revealed a higher temperature melt stability in the powders from m-cresol. It is postulated that the differences in the properties of the two powders are the result of differing initial molecular weights and a suppression of a cross-linking ketimine reaction in the polymer produced in m-cresol. / Ph. D.

processing

synthesis

LaRC polyimide

crystallization

melting

LD5655.V856 1996.B737