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Relaxation transition and

A study of the relaxational transitions and related heat capacity anomalies for galactose and fructose has been described which employs calorimetric methods. The kinetics of solution oxidation of L-ascorbic acid have been studied using an isothermal microcalorimeter. Differential scanning calorimetry (DSC) has been used to measure solid state co-crystallization of sugar alcohols (xylitol, o-sorbitol and D-mannitol), and the thermal behaviour of anticoagulant heparins. Thermal measurements indicate a role for the structural transition from hydrated P-CD to dehydrated P-CD. Calorimetry was used to establish thermodynamic parameters for (1 1) complexation equilibrium of citric acid and P-CD in water. Several thermal techniques were used to study the decomposition of p-CD inclusion complexes of ferrocene and derivatives. DSC and derivative thermogravimetric measurements have been reported for crystalline cytidine and deoxycytidine. Heats of formation have been determined for a-D-glucose esters and compared with semiempirical quantum mechanical calculations. ... [Pg.341]

Below we consider the results of our systematic research of deformation kinetics for glassy polymers over the wide ranges of temperatures and deformations, using the laser-interferometric technique under consideration [11,278,280-287], This research allowed us (1) to study the dependencies of kinetic parameters of creep on these factors, (2) to reveal the regular relations between the activation parameters of polymer creep, (3) to demonstrate their intimate connection with the parameters of relaxation transitions, and (4) to confirm directly the intermolecular physical nature of potential barriers of polymer plasticity. ... [Pg.179]

Secondary Transitions. Both amorphous and semicrystalline polymers display multiple relaxation transitions. It is customary to label relaxation transition in polymers as a, y, S, and so on, in alphabetical order with decreasing temperature, a-relaxation being the glass transition. One should, however, note that there is a lot of confusion in the classification of relaxation transitions and their interpretation. This situation is described in detail elsewhere (16,141,142). [Pg.1257]

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Glass transition and relaxations

Glass transition and secondary relaxation

Glass transition and secondary relaxation processes

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Relaxation transition

Temperature and pressure dependence of relaxation near the glass transition

Transitions and Relaxation in Polymers

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