Propagation constants aldehydes

The polar carbonyl group interacts with the polar transition state of the reaction between the peroxyl radical and the C—H bond of the aldehyde. This interaction lowers the activation energy of this reaction (see Section 8.1.4). As a result, all the three factors, viz., the strong RC(0)00—H bond formed, the weak C—H bond of the oxidized aldehyde, and the polar interaction in the transition state, contribute to lowering the activation energy of the reaction RC(0)00 + RCH(O) and increasing the rate constant of the chain propagation reaction (see Section 8.1.4). 

Rate Constants for Chain Propagation in the Oxidation of Aldehydes... 

In solvents of high dielectric constant, (e.g. dimethylformamide), formaldehyde polymerized sluggishly and polymers were formed in low yield. In similar solvents, aliphatic aldehydes could not be polymerized. Precipitated aldehyde polymers have the tendency to absorb monomers. The monomer concentration near the propagating site may be much hi er than that in the surrounding solution. This occurs with n-butyraldehyde polymerizations in pentane [5] the polymer precipitated during the polymerization is highly swollen by the monomer. 

The kinetic treatment of these polymerization reactions depends upon the establishment of stationary state equations for the rates of formation and disappearance of all the transitory intermediates. The form of the expressions derived for the rate of the main reaction depends largely upon the mode of chain ending, and the constants entering into the formulae are those characterizing initiation, propagation, and termination respectively. Special means may be employed for the study of some of these constants in isolation, whereby rather complicated relations can be unravelled. For example, the reaction may be excited photoohemically, in which case the rate of initiation is calculable from the number of quanta of light which are absorbed. This method can be applied with ease to those polymerization reactions which are started by radicals formed, for example, in the photolysis of aldehyde ... 

The effectiveness of a modifier depends on its chemical structure, concentration, temperature, and pressure. A concentration-independent measure for its effectiveness is the chain transfer constant, defined as the ratio of kinetic coefficients for the transfer reaction to this substance and radical chain propagation reaction. Usually the effectiveness of chain transfer agents is increased with rising temperature and reduced pressure. The chain transfer constant of modifiers falls from aldehydes, which are more effective than ketones or esters, to hydrocarbons. Unsaturated hydrocarbons typically have higher transfer constants than saturated hydrocarbons and a strong effect on polymer density must be considered because of the ability to copolymerize that give a higher frequency of short-chain branches in the polymer. 

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