6533b86efe1ef96bd12cb1fc

RESEARCH PRODUCT

Fragmentation of polycarbonate macroinitiators in solution and in the bulk state

G. P. HellmannK. J. Kuhn

subject

Arrhenius equationPolymers and PlasticsChemistryRadicalActivation energyCondensed Matter PhysicsDissociation (chemistry)symbols.namesakeFragmentation (mass spectrometry)visual_artPolymer chemistryMaterials Chemistryvisual_art.visual_art_mediumsymbolsPhysical and Theoretical ChemistryPolycarbonateRadical disproportionationGlass transition

description

The diphenylethane initiator 3,4-diethyl-3,4-(p-methoxyphenyl)-hexane (T–OCH3) was synthesized. By cocondensation of bisphenol A or C and the bisphenol derivative (“T”) of T–OCH3 with phosgene, polycarbonate macroinitiators PC(TxA1-x) and PC(TxC1-x) with different compositions x were made. The thermal fragmentation of T–OCH3 and the copolycarbonates was investigated with and without a radical scavenger both in solution and in the bulk state. The primary dissociation of T–OCH3 is a monomolecular Arrhenius process with a characteristic temperature of T* (τ = 1h) = 140°C (τ: average life time of the intact molecule). When the radicals are not intercepted, the dissociation is excessively reverted by radical recombination, which raises T* to T* = 163°C. The reaction ends then exclusively in radical disproportionation. The chain fragmentation of the copolycarbonates is of the type of a random decondensation. The counits CT dissociate in solution almost exactly like T–OCH3. In the highly viscous bulk state, the reaction proceeds in matrix cages, which have a stabilizing effect, so that T* is increased to T* = 170°C. These copolycarbonates are model polymers for a novel method to study the hitherto unmeasurably slow chain diffusion processes in polymers near the glass transition temperature.

yearjournalcountryeditionlanguage
1990-11-01Journal of Polymer Science Part B: Polymer Physics
https://doi.org/10.1002/polb.1990.090281201