Atom-transfer-chain

Cyclizable radical-probe experiments have been extensively used in ET versus Spj2 investigations (see Ashby, 1988, and references cited therein). Attention has, however, been recently drawn to causes of possible misinterpretation, particularly in the case of iodides, where an iodine-atom-transfer chain mechanism is able to convert most of the starting linear iodide into the cyclized iodide, even if only a minute amount of linear-chain radical is present in 7-8 2 reactions (Newcomb and Curran, 1988). Rather puzzling results were found in the reaction of (CH3)3Sn ions with secondary bromides, which should not be involved in atom-exchange chain reactions... 

An atom transfer chain mechanism very similar to that in Scheme 6 is thought to occur in some photoinitiated CO substitution reactions of organometallic halide complexes. For example, [Cp2Mo2(CO)6] promotes the photosubstitution of CO by PR3 in [CpMo(CO)3X] (X = Br, I),"9 and... 

Besides ETC catalysis, atom-transfer chain (ATC) catalysis has been reviewed [2]. The initiation involves radicals and the redox propagation step exchanges an... 

S.3 Atom-Transfer-Chain (ATC) Catalysis 3.2.8.3.1 Halogen-ATC Catalysis... 

In 1989 Curran and co-workers reported on a photocatalytically induced free-radical cyclization leading to various cyclic, bi-, or polycyclic carbocycles (fused and spiro) via isomerization of unsaturated iodides (alkenes, alkynes) [63]. This corresponds to the nonreductive variant of the tin hydride method. Under sunlight irradiation and in the presence of 10 mol% hexabutylditin, a-iodo esters, ketones, and malonates are efficiently transformed via an iodide atom transfer chain mechanism (eq. (4)). 

Brown has shown that metal-carbonyl-hydride complexes such as [Re(H)(CO)s] can nndergo CO substitntion by a phosphine (PBus) according to the H-atom-transfer-chain mechanism A classic type of initiation to introduce the radical species into the chain is to photolyze the metal-carbonyl dimer, which generates the reactive 17-electron metal-carbonyl monomer ... 

Likewise, concerning the reactions of the type [MFl] -1- RX — [MX] -1- RH, it is often difficult to distinguish between the mechanisms (a) hydride transfer, (b) electron transfer followed by H atom transfer (non chain) and (c) atom-transfer chain (ATC, see Chap. 4). 

Electron-transfer-chain and atom-transfer-chain mechanisms.127... 

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. 

Benzene may react by addition as shown in Scheme 6.12 (this pathway is also open to other aromatic solvents). The cyclohexadienyl radical is a poor initiating species and may terminate a second chain by hydrogen atom transfer. According to this process, benzene is a retarder rather than a transfer agent. 

To avoid these stability problems, it is necessary to minimize the proportion of chains that terminate by radical-radical reaction. One way of achieving this is to conduct the polymerization in the presence of an appropriate chain transfer agent. For example, if polymerization is performed in the presence of a H-donor chain transfer agent, conditions can be chosen such that most chains terminate by hydrogen-atom transfer. Bagby et al.iA examined the thermal stability of PMMA formed with dodecanethiol. These polymer chains will then possess, more... 

The addition of halocarbons (RX) across alkene double bonds in a radical chain process, the Kharasch reaction (Scheme 9.29),261 has been known to organic chemistry since 1932. The overall process can be catalyzed by transition metal complexes (Mt"-X) it is then called Atom Transfer Radical Addition (ATRA) (Scheme 9.30).262... 

The catalysts 153-155 shown in Table 9.7 have been used for polymerizations of acrylates and methacrylates and S. The catalyst 155 used in conjunction with an iodo compound initiator has also been employed for VAc polymerization.3"0 Catalytic chain transfer (Section 6.2.5) occurs in competition with halogen atom transfer with some catalysts. 

ORl OX w di-Miutyl peroxyoxalalc deactivation by reversible chain transfer and bioinolecular aclivaiion 456 atom transfer radical polymerization 7, 250, 456,457, 458,461.486-98 deactivation by reversible coupling and untmolecular activation 455-6, 457-86 carbon-centered radical-mediated poly nierizaiion 467-70 initiators, inferlers and iriiters 457-8 metal complex-mediated radical polymerization 484... 

This is one of the steps in the copper-catalyzed redox-transfer chain addition of arenesulfonyl chlorides to styrenes (vide infra). The p-value of + 0.56 indicates the involvement of a simple atom transfer as well as a polar contribution to the transition state. 

Silane radical atom transfer (SRAA) was demonstrated as an efficient, metal-free method to generate polystyrene of controllable molecular weight and low polydispersity index values. (TMSlsSi radicals were generated in situ by reaction of (TMSlsSiH with thermally generated f-BuO radicals as depicted in Scheme 14. (TMSlsSi radicals in the presence of polystyrene bromide (PS -Br), effectively abstract the bromine from the chain terminus and generate macroradicals that undergo coupling reactions (Reaction 70). 

The reactivity shown in Scheme 3 results from the low bond dissociation energy (BDE) of the P-H bond [11] k=l.2 10 M s for the H-transfer from R02P(0)H to a primary C-centered radical) and the fast halogen-atom transfer from a C-halogen bond to a phosphonyl radical [9,12] (fc=4 10 M s for f-Bu-Br and k=83 10 M s for Cl3C-Br). Piettre et al. [13] pointed out that these chain reactions were even more efficient when dialkylthiophosphites and the corresponding dialkylphosphinothioyl radicals were involved. 

In 2003, the van Hest group produced elastin-based side-chain polymers [123]. This research was motivated by the demonstration of the occurrence of an inverse temperature transition in a single repeat of VPGVG [124]. A methacrylate-functionalized VPGVG was synthesized and used as a monomer to perform atom transfer radical polymerization (ATRP) to produce homopolymers (Fig. 16b) or... 

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