Radicals polymerization induced

Scheme 24 summarizes the possible processes that can occur during a free-radical polymerization induced via an intermolecular electron transfer process (PET) in the presence of aromatic amines kdii is the rate constant of diffusive encounters be-... 

Polycarbosilanes with silicon-containing six-membered rings in the backbone can be synthesized by cyclopolymerization of organosihcon monomers bearing two olefinic substituents. Poly(methylene-(l-sila-3,5-cyclohexanylene))s (15) are obtained by cyclopolymerization of dialkyldiallylsilanes. Coordination polymerization by Ziegler-type catalysts (87-89), cationic polymerization by AlBrs (90-92), and radical polymerization induced by AIBN (93) have been reported (eq. 15). 

M.p. 296 C. Accepts an electron from suitable donors forming a radical anion. Used for colorimetric determination of free radical precursors, replacement of Mn02 in aluminium solid electrolytic capacitors, construction of heat-sensitive resistors and ion-specific electrodes and for inducing radical polymerizations. The charge transfer complexes it forms with certain donors behave electrically like metals with anisotropic conductivity. Like tetracyanoethylene it belongs to a class of compounds called rr-acids. tetracyclines An important group of antibiotics isolated from Streptomyces spp., having structures based on a naphthacene skeleton. Tetracycline, the parent compound, has the structure ... 

Because they are acrylic monomers, alkyl cyanoacrylate esters still require the addition of radical polymerization inhibitors, such as hydroquinone or hindered phenols, to prevent radically induced polymerization over time [3j. Since basic initiation of alkyl cyanoacrylate monomers is the predominant polymerization mechanism, large quantities of free radical inhibitors can be added, with little or no effect on adhesive performance. 

Many of the initiators used in radical polymerization arc susceptible to induced decomposition by various radical species. When the reaction involves the... 

The C-S bond of the sulfide end groups can be relatively weak and susceptible to thermal and photo- or radical-induced homolysis. This means that certain disulfides [for example 7-9] may act as iniferters in living radical polymerization and they can be used as precursors to block copolymers (Sections 7.5.1 and 9.3.2). 

Bhawe (14) has simulated the periodic operation of a photo-chemically induced free-radical polymerization which has both monomer and solvent transfer steps and a recombination termination reaction. An increase of 50% in the value of Dp was observed over and above the expected value of 2.0. An interesting feature of this work is that when very short period oscillations were employed, virtually time-invariant products were predicted. 

The most comprehensive simulation of a free radical polymerization process in a CSTR is that of Konopnicki and Kuester (15). For a mechanism which includes transfer to both monomer and solvent as well as termination by combination and disproportionation they examined the influence of non-isothermal operation, viscosity effects as well as induced sinuoidal and square-wave forcing functions on initiator feed and jacket temperature on the MWD of the polymer produced. 

The theory of radiation-induced grafting has received extensive treatment [21,131,132]. The typical steps involved in free-radical polymerization are also applicable to graft polymerization including initiation, propagation, and chain transfer [133]. However, the complicating role of diffusion prevents any simple correlation of individual rate constants to the overall reaction rates. Changes in temperamre, for example, increase the rate of monomer diffusion and monomer... 

Styrene Free radical polymerization similar to the above. Also susceptible to rapid cationic polymerization induced by AlCb at —80°C and to anionic polymerization using alkali metals or their hydrides —CH2—CH— (ieHs T = 100 Amorphous, even when stretched. Hard. Soluble in aromatic hydrocarbons, higher ketones, and esters... 

Free radical polymerization is slow and yields only very low polymers. Vigorous cationic polymerization induced by BFs-ether complex at temperatures down to —... 

Not susceptible to free radical or anionic polymerization, but cationic polymerization induced by BFs, AICI3, etc., is extremely rapid even at — 100°C... 

The role of reactive centers is performed here by free radicals or ions whose reaction with double bonds in monomer molecules leads to the growth of a polymer chain. The time of its formation may be either essentially less than that of monomer consumption or comparable with it. The first case takes place in the processes of free-radical polymerization whereas the second one is peculiar to the processes of living anionic polymerization. The distinction between these two cases is the most greatly pronounced under copolymerization of two and more monomers when the change in their concentrations over the course of the synthesis induces chemical inhomogeneity of the products formed not only for size but for composition as well. 

The accepted kinetic scheme for free radical polymerization reactions (equations 1-M1) has been used as basis for the development of the mathematical equations for the estimation of both, the efficiencies and the rate constants. Induced decomposition reactions (equations 3 and 10) have been Included to generalize the model for initiators such as Benzoyl Peroxide for... 

A half-metallocene iron iodide carbonyl complex Fe(Cp)I(CO)2 was found to induce the living radical polymerization of methyl acrylate and f-bulyl acrylate with an iodide initiator (CH3)2C(C02Et)I and Al(Oi- Pr)3 to provide controlled molecular weights and rather low molecular weight distributions (Mw/Mn < 1.2) [79]. The living character of the polymerization was further tested with the synthesis of the PMA-fc-PS and PtBuA-fi-PS block copolymers. The procedure efficiently provided the desired block copolymers, albeit with low molecular weights. 

In 1957, Otsu and coworkers reported that the polymer obtained from St with 13 could induce the radical polymerization of second monomers leading to block copolymers [70-74]. Poly(St)-hZock-poly(MMA), poly(St)-hZock-poly (AN), poly(St)-Z Zock-poly(VAc), and poly(St)-hZock-poly(VA) were prepared from the end-functional poly(St) [75], In the photopolymerization of St and MMA with 13, it was also confirmed that the molecular weight of the polymers produced linearly increased with the reaction time, although the reaction mechanism was not ascertained at that time. Thereafter, the poly(St) produced with 13 was confirmed to have two DC end groups, which can further dissociate pho-tochemically [76]. 

In 1984, Solomon et al. [78-80] also independently reported that some alkoxyamines and related compounds induced living radical polymerization (Eq. 20), being similar to Eq. (18). 

The resulting polymers can further induce the radical polymerization of second monomers to give block copolymers. The polymerization with the alkoxyamines has developed to the recent living radical polymerization providing polymers with well-controlled molecular weight and molecular weight distribution, as will be described in Sect 6.1. 

In 1939, Schulz [92-94] first reported that 12 (X=CN in 21) served as an initiator for the radical polymerization of MM A and St. Thereafter, Hey and Misra [95] also reported the polymerization of St with 12 or its p-methoxy substituted derivatives. Borsig et al. [96,97] reported in 1967 the polymerization of MMA and St with 3,3,4,4-tetraphenylcyclohexane (21b) and 1,1,2,2-tetraphenylcyclopentane (21c) and that the reaction orders of the polymerization rates with respect to the concentrations of 21b and 21c were 0.25 and 0.20, respectively, and concluded that the primary radical termination predominantly occurred. It was noted that in these polymerizations the average molecular weight of the polymer increased as a function of the polymerization time, although the clear reason was not described in these papers. It was also reported by the same authors that the resulting polymer could further induce block copolymerization [98]. 

In the polymerization of St, it was found that 12 scarcely induces living radical polymerization [111], because the C-C bond of the co-chain end is a pentasubsti-tuted ethane structure (23), while the co-chain end of the polymer produced from the polymerization of MMA is a dissociable hexasubstituted ethane structure (24). The non-dissociation properties of the co-chain end of the polymer produced in the St polymerization were also reported by Braun et al. [109,112-116]. Namely, the St polymerization with 12 was a dead-end type polymerization. The dissociation of the chain ends was also examined by the experiments using the oligomer (n=l-3in24) [117,118] or amodel compound of the chain-end structures, 25 [119]. The C-C bond length at the co-chain end is 1.628 A for 24 (n=l), which is longer than the ordinary C-C bonds [118]. 

Similarly, it was also found that radical polymerization was induced in the Ni(CO)3(PPh3)/CBrCl3 redox system [155]. This complex is soluble in the polymerization medium, and the polymerization proceeded in a homogeneous system. This redox iniferter system has been intensively developed to the recent successful living radical polymerization using transition-metal complexes in combination with alkyl halides by several independent research groups (see Sect. 6.2). 

Tetraethylthiuram disulfide (13) induces St polymerization by the photodissociation of its S-S bond to give the polymer with C-S bonds at both chain ends (15). The C-S bond further acts as a polymeric photoiniferter, resulting in living radical polymerization. Eventually, some di- or monosulfides, as well as 13, were also examined as photoiniferters and were found to induce polymerization via a living radical polymerization mechanism close to the model in Eq. (18), e.g., the polymerization of St with 35 and 36 [76,157]. These disulfides were used for block copolymer synthesis [75,157-161] ... 

It was confirmed that the resulting polymers obtained from the St polymerization with 13 induced further photopolymerization of MMA to produce a block copolymer, and the yield and molecular weight increased as a function of the polymerization time, similar to the results for the polymerization of MMA with 13, indicating that this block copolymerization also proceeds via a living radical polymerization mechanism [64]. Similar results were also obtained for the photoblock copolymerization of VAc. Thus, various kinds of two- or three-component block copolymers were prepared [157,158]. 

In the co-end of the chain, the dissociation always occurs at the bond which is indicated by the arrow A. The dissociation of this C-S bond at the A position gives a more-reactive carbon-centered radical and a less-reactive polymer thiyl radical, which leads to the termination of the active chain ends. In the case of the a-chain end, however, there is a possibility that the bond at the C position dissociates to produce a diethylaminothiocarbonyl radical and a thiyl radical in addition to the preferable bond scission at B. Such dissociation at C may not induce living radical polymerization [76]. 

The dissociation of model compounds for co-chain ends of polymers obtained using iniferters with the DC group was examined by the spin-trapping technique, similar to the disso dation of 7 and 8 previously mentioned [174,175]. From the results of the trapping experiments, it was concluded that 46,47, and 48 as model compounds for poly(MA), poly(MMA), and poly(VAc), respectively, dissociated at the appropriate position to produce a reactive carbon-centered radical and a stable DC radical. In fact, these compounds were found to induce the living radical polymerization of St when they were used as photoiniferters. 

It was found that the adduct 59 also induces living radical polymerization similar to 56, but the adduct 60 does not [215]. In the polymerization of St with 60, the molecular weight did not increase with conversion, and a broad molecular weight distribution, i.e., Mw/Mn of 1.5-2.2 was observed. The half-fife time was determined to be 5-10 min at 123 °C for 59, while that of 60 is much longer (ca. 150 min). The dissociation properties of the alkoxiamines used determined the nature of the polymerization with 59 and 60. 

Nitroxide attached to macromolecules also induces the living radical polymerization of St. Yoshida and Sugita [252] prepared a polymeric stable radical by the reaction of the living end of the polytetrahydrofuran prepared by cationic polymerization with 4-hydroxy-TEMPO and studied the living radical polymerization of St with the nitroxide-bearing polytetrahydrofuran chain. The nitroxides attached to the dendrimer have been synthesized (Eq. 69) to yield block copolymers consisting of a dendrimer and a linear polymer [250,253]. 

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. 

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