Other Living Radical Polymerizations

Xanthates have also been used as RAFT agents. RAFT polymerization has been observed for methacrylate monomers using double bond end-capped methacrylate oligomers [Gridnev and Ittel, 2001], 

The presence of 1,1-diphenylethene (DPE) in the polymerization of a monomer results in a living polymerization [Raether et al., 2002 Wieland et al., 2002]. DPE adds reversibly to a propagating chain to form a dormant stable radical with no (or very low) reactivity to add monomer. This sets up an equilibrium between propagating chains (active species) and dormant DPE-terminal radicals. 

Other systems include organotellurium and boroxyl-based initiators [Chung et al., 1996 Yamago et al., 2002). 

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The synthesis of complex polymer architectures by ATRP (or other living radical polymerizations) is useful but relatively restricted because the occurrence of bimolecular termination increases with the number of initiator sites on a polymeric species. 

RAFT [188-190] is known for its compatibility with a wide range of monomers, temperature, and impurities, as compared to other living radical polymerizations such as ATRP and NMP. 

To examine potentiality of other ylides and their metal complex containing Sb, As, P, Bi, and Se as new novel initiator in polymer synthesis via living radical polymerization. 

In each of the sections below, we will consider the initiation process separately. For each system, various initiation methods have been applied. In some cases the initiator is a low molecular weight analog of the propagating species, in other cases it is a method oT generating such a species. The initiators first used in this form of living radical polymerization were called iniferters (initiator - transfer agent - chain terminator) or initers (initiator - chain terminator). 

Of the major methods for living radical polymerization, NMP appears the most successful for polymerization of the diene monomers. There are a number of reports on the use of NMP of diene monomers (B, I) with TEMPO,188,1103 861 4, cw and other nitroxides.127 High reaction temperatures (120-135 °C) were employed in all cases. The ratio of 1,2- 1,4-cis 1,4-trans structures obtained is similar to that observed in conventional radical polymerization (Section 4.3.2). 

NMP of S in heterogeneous media is discussed in reviews by Qiu et at.,205 Cunningham,206 207 and Schork et a/.208 There have been several theoretical studies dealing with NMP and other living radical procedures in emulsion and miniemulsion."09 213 Butte et nr/.210 214 concluded that NMP (and ATRP) should be subject to marked retardation as a consequence of the persistent radical effect. Charlcux209 predicted enhanced polymerization rates for minicmulsion with small... 

As with other forms of living radical polymerization, the degree of polymerization and the molecular weight can be estimated from the concentration of monomer and reagents as shown in eqs. 13 and 14 respectively. 183... 

Living radical polymerization using thiocarbonylthio RAFT agents (including dithioesters, trithiocarbonates and xanthates) was first described in a patent published in 1998.40S The first paper describing the process also appeared in 1998.1R Other patents and papers soon followed. Papers on this method, along with NMP and ATRP, now dominate the literature on radical polymerization. 

Living Radical Polymerization Table 9.11 Other Aromatic Dithioester RAFT Agents... 

As is expected from these results, it is very difficult to control the polymerization of monomers other than St, e.g., that of MMA, because of the too small dissociation energy of the chain end of poly(MMA). In fact, the polymerization of MMA in the presence of TEMPO yielded the polymer with constant Mn irrespective of conversion, and the Mw/Mn values are similar to those of conventional polymerizations [216]. The disproportionation of the propagating radical and TEMPO would also make the living radical polymerization of MMA difficult. In contrast, the controlled polymerization of MA, whose propagating radical is a secondary carbon radical,has recentlybeen reported [217]. Poly(MA) with a narrow molecular weight distribution and block copolymers were obtained. 

The living radical polymerization of some derivatives of St was carried out. The polymerizations of 4-bromostyrene [254], 4-chloromethylstyrene [255, 256], and other derivatives [257] proceed by a living radical polymerization mechanism to give polymers with well-controlled structures and block copolymers with poly(St). The random copolymerization of St with other vinyl... 

Sawamoto et al. have revealed that the ruthenium complex induces the living radical polymerization of MMA [30,273-277]. For example, RuCl2(PPh)3 provided poly(MMA) with Mw/Mn 1.1 and the block copolymers. This system has a unique characteristic in that it is valid not only for MMA and other methacrylates, but also for acrylates and St derivatives. 

Coordination Polymerization of 1,3-Dienes Single-Site (or Metallocene) Catalysts Living Radical Polymerizations Other Types of Polymerizations, Polymers Ring-Opening Polymerization... 

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