Cyclizations propagation

Allyl group containing polymers have been found to cross-link readily on e-beam exposure. Free radical solution polymerization of allyl methacrylate has been shown to result in a unique polymer with about 65% pendant allyl groups and the remainder believed to be involved in a cyclization propagation step. The exact structure of this polymer has yet to be established however, it differs significantly in physical properties from anionically prepared poly(allyl methacrylate), which has a structure with 100% pendant allyl groups. The of the former polymer is llO C, compared to the latter, which is 36 The free radically prepared polymer is very sensitive to e-beam radiation (1.5 X 10"Ccm" at lOkeV) but has poor physical properties such as adhesion, etc. Copolymerization of allyl methacrylate with glycidyl methacrylate results in copolymers with equivalent... 

The and e values of the aHyl group in DAP have been estimated as 0.029 and 0.04, respectively, suggesting that DAP acts as a fairly typical unconjugated, bifunctional monomer (42). Cyclization affects copolymerization, since cyclized radicals are less reactive in chain propagation. Thus DAP is less reactive in copolymerization than DAIP or DATP where cyclization is stericaHy hindered. Particular comonomers affect cyclization, chain transfer, and residual unsaturation in the copolymer products. DiaHyl tetrachloro- and tetrabromophthalates are low in reactivity. 

Cyclizations involving iodine-atom transfers have been developed. Among the most effective examples are reactions involving the cyclization of 6-iodohexene derivatives. The 6-hexenyl radical generated by iodine-atom abstraction rapidly cyclizes to a cyclo-pentylmethyl radical. The chain is propagated by iodine-atom transfer. 

The chain is propagated by abstraction of iodine by the cyclized vinyl radical intermediate. 

Wawzonek et al. first investigated the mechanism of the cyclization of A-haloamines and correctly proposed the free radical chain reaction pathway that was substantiated by experimental data. "" Subsequently, Corey and Hertler examined the stereochemistry, hydrogen isotope effect, initiation, catalysis, intermediates, and selectivity of hydrogen transfer. Their results pointed conclusively to a free radical chain mechanism involving intramolecular hydrogen transfer as one of the propagation steps. Accordingly, the... 

Propagation in cyclopolymerization may be substantially faster than for analogous monoene monomers.15" The various theories put forward to account for this observation are summarized in Butler s review.98 A recent theoretical study by Ttiziin et al.u3 looks at the effects of substituents on the rate of the cyclization step. 

Geometric considerations would seem to dictate that 1,4- and 1,5-dicncs should not undergo cyclopolymerization readily. However, in the case of 1,4-dienes, a 5-hexenyl system is formed after one propagation step. Cyclization via 1,5-backbiling generates a second 5-hexenyl system. Homopolymerization of divinyl ether (22) is thought to involve such a bicyclization. The polymer contains a mixture of structures including that formed by the pathway shown in Scheme 4.18. 

The previously outlined mechanistic scheme, postulating reversible propagation and cyclization, was simplified by neglecting the de-cyclization because in the very short time of the studied reaction the extent of de-cyclization is negligible. The rate constants appearing in the appropriate differential equations were computer adjusted until the calculated conversion curves, shown in Fig. 7, fit the experimental points. The results seem to be reliable inspite of the stiffness of the differential equations. 

These cyclizations can also be carried out without a hydrogen donor, in which case the chain is propagated by iodine atom transfer.331 If necessary, ethyl iodide can be added to facilitate iodine atom transfer. 

To explain the formation of non-crosslinked polymers from the diallyl quaternary ammonium system, Butler and Angelo proposed a chain growth mechanism which involved a series of intra- and inter-molecular propagation steps (15). This type of polymerization was subsequently shown to occur in a wide variety of symmetrical diene systems which cyclize to form five or six-membered ring structures. This mode of propagation of a non-conjugated diene with subsequent ring formation was later called cyclopolymerization. 

The most studied catalyst family of this type are lithium alkyls. With relatively non-bulky substituents, for example nBuLi, the polymerization of MMA is complicated by side reactions.4 0 These may be suppressed if bulkier initiators such as 1,1-diphenylhexyllithium are used,431 especially at low temperature (typically —78 °C), allowing the synthesis of block copolymers.432,433 The addition of bulky lithium alkoxides to alkyllithium initiators also retards the rate of intramolecular cyclization, thus allowing the polymerization temperature to be raised.427 LiCl has been used to similar effect, allowing monodisperse PMMA (Mw/Mn = 1.2) to be prepared at —20 °C.434 Sterically hindered lithium aluminum alkyls have been used at ambient (or higher) temperature to polymerize MMA in a controlled way.435 This process has been termed screened anionic polymerization since the bulky alkyl substituents screen the propagating terminus from side reactions. 

After the first dehydration step, the reaction propagates by successive dehydration-methanolation steps, competing with poly-merization-cyclization-aromatization processes. The existence of dehydration-methanolation mechanism is inferred from the constant presence of a small amount of methanol (from in situ C-NMR observation) on the catalyst. Further evidence has been acquired in favor of the carbenium ion chain-growth mechanism from the l C-NMR study of CO incorporation into the products during the conversion of methanol (46). 

In the gluco case (Scheme 13) the radical cyclization, with its requirement for the formation of a czs-fused ring junction [129,130], takes place uneventfully on the opposite face of the alkene radical cation to the one shielded by the phosphate anion, whereas in the manno series cyclization is severely retarded by the presence of the phosphate group above the face of the radical cation on which cyclization must occur. This steric retardation of the cyclization step results in a breakdown of chain propagation and results in the longer reaction times observed. Furthermore, the retardation of the radical cyclization step in the manno case enables the alkene radical cation to take... 

The cyclization of 8, s-unsaturated acyl radicals has been the research subject of several groups [27]. The propagation steps for the prototype reaction are illustrated in Scheme 7.4. The 5-exo 6-endo product ratio varies with the change of the silane concentration due to the competition of hydrogen abstraction from the silane with the ring expansion path. 

Scheme 7.4 Propagation steps involving the cyclization of acyl radicals...

It was proposed that an initially generated silyl radical 3, by reaction of i-BuO radical and polysilane 2, attacks another silicon atom in the same backbone to give a cyclic polysilane that contains an acyclic chain and another silyl radical (Scheme 8.1) [12]. The last silyl radical can either cyclize or abstract a hydrogen atom from another macromolecule, thus propagating the chain degradation. The reaction in Scheme 8.1 is an example of intramolecular homolytic substitution (ShO, a class of reactions discussed in Chapter 6. 

Electroreductive one-electron initiation of cyclization was described for the series of E,E-, 1-dibenzoyl-l,6-heptadiene and its derivatives (Roh et al. 2002, Felton and Bauld 2004). In this case, the catalytic effect was also observed (the actual consumption of electricity was substantially less than theoretical). The same bis(enones) can also be cyclized on the action of the sodium salt of chrysene anion-radical in THF, but with no catalytic effect. Optimum yields were obtained only when 70-120 mol% of the initiator was used, relative to a substrate (Yang et al. 2004). The authors suggest that tight ion pairing of the sodium cation with the product anion-radical in THF (which is a somewhat nonpolar solvent) slows down the intermolecular electron transfer to the bis(enone) molecules. Such an electron transfer would be required for chain propagation. 

The importance of intramolecular cyclization was emphasized when Butler and coworkers found that the radical polymerization of N, N, N, /V-diallyldimethylammonium chloride (DADMAC) gave soluble, uncrosslinked polymers with little or no unsaturation (Eq. 6-101) [Butler and Angelo, 1957 Butler and Ingley, 1951 Wandrey et al., 1999]. There is a very low tendency for radical IV to propagate intermolecularly and undergo crosslinking. The predominant reaction is intramolecular cyclization, and the product is a linear product with cyclic structures in the backbone. The reaction is referred to as alternating intra/intermolecular polymerization or cyclopolymerization. 

The competition between the rates of intermolecular propagation Rp and intramolecular cyclization Rc can be expressed in terms of the fraction of cyclized units fc defined by... 

Various mechanisms have been proposed to account for cyclization of 1,3-dienes. Cyclization probably occurs by attack of the propagating carhocation on trans 1,4-douhle bonds,... 

Secondary reactions usually proceed in addition to template polymerization of the system template-monomer-solvent. They influence both kinetics of the reaction and the structure of the reaction products. Depending on the basic mechanism of reaction, typical groups of secondary reactions can take place. For instance, in polycondensation, there are such well known reactions as cyclization, decarboxylation, dehydratation, oxidation, hydrolysis, etc. In radical polymerization, usually, in addition to the main elementary processes (initiation, propagation and termination), we have the usual chain transfer to the monomer or to the solvent which change the molecular weight of the product obtained. Also, chain transfer to the polymer leads to the branched polymer. 

Molar Cyclization Equilibrium Constant (Kx) and the Rate Constant of Propagation (kp x) and Depropagation (kj x) for Cyclic x-mer at 0eC with LiO-t-Bu (4.5xl0-3M)... 

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