Sorption,Diffusion,and Dilation in Linear and Branched Polycarbonate–CO 2 Systems in Relation to Solid State Processing of Microcellular Foams 1

Abstract

The sorption and diffusion of CO₂ in linear and branched polycarbonates were investigated using a high-temperature, high-pressure gravimetric technique. The branched structure does not affect gas solubility, but affects the gas diffusivity in the sub-T_g region, with CO₂ diffusing faster through the branched structure than the linear one. Both solubility and diffusivity depend linearly on pressure at temperatures above T_g, but demonstrate complicated pressure dependence at temperatures below T_g. In the sub-T_g region, volume change of the polymer matrix accompanying the gas dissolution was measured using a dilatometer. The plasticized T_gs obtained from dilation and solubility measurements agreed with those obtained directly by high-pressure DSC. In addition, a plasticization related densification phenomenon was observed in the sub-T_g region. The competing effects of dilation and densification suggest significant implications in terms of solid state processing of microcellular foams.

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