Nitrile groups, conjugating effects

Many substituents stabilize the monomer but have no appreciable effect on polymer stability, since resonance is only possible with the former. The net effect is to decrease the exothermicity of the polymerization. Thus hyperconjugation of alkyl groups with the C=C lowers AH for propylene and 1-butene polymerizations. Conjugation of the C=C with substituents such as the benzene ring (styrene and a-methylstyrene), and alkene double bond (butadiene and isoprene), the carbonyl linkage (acrylic acid, methyl acrylate, methyl methacrylate), and the nitrile group (acrylonitrile) similarly leads to stabilization of the monomer and decreases enthalpies of polymerization. When the substituent is poorly conjugating as in vinyl acetate, the AH is close to the value for ethylene. 

Limited examples of substituted alkyl radical clocks are available. Fortunately, some calibrated clocks that are available have rate constants in the middle ranges for radical reactions and should be useful in a number of applications. Examples of clocks based on the 5-exo cyclization of the 5-hexenyl radical are shown in Table 2. The data for the series of radicals 2-1 and 2-2 [17, 32, 34, 35] are from indirect studies, whereas the data for radicals 2-3 and 2-4 [3, 35-38] are from direct LFP studies. The striking feature in these values is the apparent absence of electronic effects on the kinetics as deduced from the consistent values found for secondary radicals in the series 2-1 and 2-3. The dramatic reduction in rate constants for the tertiary radical counterparts that contain the conjugating ester, amide and nitrile groups must, therefore, be due to steric effects. It is likely that these groups enforce planarity at the radical center, and the radicals suffer a considerable energy penalty for pyramidalization that would relieve steric compression in the transition states for cyclization. 

The largest shifts come from groups that withdraw electrons by conjugation. Nitro is the most powerful—this should not surprise you as we saw the same in non-aromatic compounds in both i C and NMR spectra. Then come the carbonyl and nitrile group followed by groups showing simple inductive withdrawal. CF3 is an important example of this kind of group-three fluorine atoms combine to exert a powerful effect. 

The bicyclic tropane ring of cocaine of course presented serious synthetic difficulties. In one attempt to find an appropriate substitute for this structural unit, a piperidine was prepared that contained methyl groups at the point of attachment of the deleted ring. Condensation of acetone with ammonia affords the piperidone, 17. Isophorone (15) may well be an intermediate in this process conjugate addition of ammonia would then give the aminoketone, 16. Further aldol reaction followed by ammonolysis would afford the observed product. Hydrogenation of the piperidone (18) followed then by reaction with benzoyl chloride gives the ester, 19. Ethanolysis of the nitrile (20) affords alpha-eucaine (21), an effective, albeit somewhat toxic, local anesthetic. 

Unsaturated nitro compound and nitriles do not usually suffer nucleophilic attack by enols or enolates and both are good at conjugate addition. The addition of the morpholine enamine 57 of cyclohexanone to 58 demonstrates that the nitro group is more effective than the ester at promoting conjugate addition.7... 

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