Styrenes transfer hydrogenation

Brunner, Leitner and others have reported the enantioselective transfer hydrogenation of alpha-, beta-unsaturated alkenes of the acrylate type [50]. The catalysts are usually rhodium phosphine-based and the reductant is formic acid or salts. The rates of reduction of alkenes using rhodium and iridium diamine complexes is modest [87]. An example of this reaction is shown in Figure 35.8. Williams has shown the transfer hydrogenation of alkenes such as indene and styrene using IPA [88]. 

Numerous enantioselective transfer hydrogenation processes have now been developed and operated at commercial scale to give consistent, high-quality products, economically. These include variously substituted aryl alcohols, styrene oxides and alicyclic and aliphatic amines. Those discussed in the public domain include (S)-3-trifluoromethylphenylethanol [48], (f )-3,5-bistrifluorophenylethanol [64], 3-nitrophenylethanol [92], (S)-4-fluorophenylethanol [lc], (f )-l-tetralol [lc], and (T)-l-methylnaphthylamine [lc]. 

The catalyst is also effective for the reduction of styrenes, ketones, and aldehydes. Cyclohexenone 16 was reduced to cyclohexanone 11 by transfer hydrogenation, and using a higher catalyst loading, styrene 17 was reduced to ethylbenzene 18. The elaboration of [Ir(cod)Cl]2 into the triazole-derived iridium carbene complex 19 provided a catalyst, which was used to reduce aUcene 20 by transfer hydrogenation [25]. 

This reaction may account in part for the oligomers obtained in the polymerization of pro-pene, 1-butene, and other 1-alkenes where the propagation reaction is not highly favorable (due to the low stability of the propagating carbocation). Unreactive 1-alkenes and 2-alkenes have been used to control polymer molecular weight in cationic polymerization of reactive monomers, presumably by hydride transfer to the unreactive monomer. The importance of hydride ion transfer from monomer is not established for the more reactive monomers. For example, hydride transfer by monomer is less likely a mode of chain termination compared to proton transfer to monomer for isobutylene polymerization since the tertiary carbocation formed by proton transfer is more stable than the allyl carbocation formed by hydride transfer. Similar considerations apply to the polymerizations of other reactive monomers. Hydride transfer is not a possibility for those monomers without easily transferable hydrogens, such as A-vinylcarbazole, styrene, vinyl ethers, and coumarone. 

Figure 2.1.8. Effect of liquid velocity on the apparent reaction rate for a reaction in a fixed bed reactor limited by gas/liquid mass transfer. Hydrogenation of alpha methyl styrene on 2.5% Pd/Al203 (p and 0.75% Pd/Al203 (II). Calculated apparent rate assuming liquid contacting/mass transfer as the only limitations (I, II ) (after Herskowitz, M., R. G. Carbonell and J. M. Smith [24J. Reproduced permission AIChE.

Ethylbenzene is disintegrated in the well-known initiation reaction (1). Methyl initiates the reaction chain in which styrene and hydrogen are formed. Toluene is formed in the transfer reaction (5), while in the two reactions (6) and (7) recombination of radicals occurs. 

In the case of styrene, direct hydrogen abstraction is unlikely, since the chain transfer coefficient of ethylbenzene is significantly lower than that of styrene. So the hydrogen is rather abstracted from a Diels-Alder adduct of two styrene molecules, where the carbon hydrogen bonds are comparatively weak. 

The results of chain transfer studies with different polymer radicals are compared in Table XIV. Chain transfer constants with hydrocarbon solvents are consistently a little greater for methyl methacrylate radicals than for styrene radicals. The methyl methacrylate chain radical is far less effective in the removal of chlorine from chlorinated solvents, however. Vinyl acetate chains are much more susceptible to chain transfer than are either of the other two polymer radicals. As will appear later, the propagation constants kp for styrene, methyl methacrylate, and vinyl acetate are in the approximate ratio 1 2 20. It follows from the transfer constants with toluene, that the rate constants ktr,s for the removal of benzylic hydrogen by the respective chain radicals are in the ratio 1 3.5 6000. Chain transfer studies offer a convenient means for comparing radical reactivities, provided the absolute propagation constants also are known. 

Bartlett and co-workers concluded that addition to the nitro group also occurs. Price and Read found that several m-dinitrobenzene molecules were combined with the polymer for each fragment from the p-bromobenzoyl peroxide used as initiator in the retarded polymerization of styrene. They inferred that the radical corresponding to IV transfers its hydrogen atom to a molecule of styrene as follows ... 

Heteropoly acids can be synergistically combined with phase-transfer catalysis in the so-called Ishii-Venturello chemistry for oxidation reactions such as oxidation of alcohols, allyl alcohols, alkenes, alkynes, P-unsaturated acids, vic-diols, phenol, and amines with hydrogen peroxide (Mizuno et al., 1994). Recent examples include the epoxidations of alkyl undecylenates (Yadav and Satoskar, 1997) and. styrene (Yadav and Pujari, 2000). 

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