Stannyl radical

If selenide additions are carried out in the presence of tri- -butylstannane, the radical generated by addition can be reduced by hydrogen abstraction. The chain is then continued by selenide abstraction by the stannyl radical. This leads to nonselenated addition and cyclization products. 

The development of sophisticated new experimental techniques during the last decade has made possible the isolation of stable representatives of the free radical species featuring an nnpaired electron on the heavier group 14 elements, that is, silyl, germyl, and stannyl radicals. This great progress in the isolation of the stable radicals opens unprecedented possibilities for their structural characterization in the crystalline form, which in tnrn enables the direct comparison of the fundamental differences and similarities between the solntion and solid state strnctnres of the free radical species. " ... 

The reduction of the stannyl radical (t-Bu2MeSi)3Sn with alkali metals produces a variety of structural modifications depending on the solvent used (Scheme 2.55). Thus, in nonpolar heptane, a dimeric stannyllithium species [58c Li ]2 (E = Sn) was formed, whereas in more polar benzene, the monomeric pyramidal structure 58c [Ti -Li (C6H5)] was produced. In the latter compound the Li+ ion was covalently bonded to the anionic Sn atom being at the same time n -coordinated to the benzene ring. A similar monomeric pyramidal CIP 58c [Li (thf)2] was prepared by reduction in polar THE the addition of [2.2.2]cryptand to this compound resulted in the isolation of the free stannyl anion 58c K+([2.2.2]cryptand), in which the ion lacked its bonding to the Sn atom. ... 

The first solution ESR spectra of the transient radicals were observed in 1969 and 1972. Silyl radicals see refs. 121a,c. Germyl radicals see ref 121a. Stannyl radicals ref. 97. 

There is a discussion of some of the sources of radicals for mechanistic studies in Section 11.1.4 of Part A. Some of the reactions discussed there, particularly the use of azo compounds and peroxides as initiators, are also important in synthetic chemistry. One of the most useful sources of free radicals in preparative chemistry is the reaction of halides with stannyl radicals. Stannanes undergo hydrogen abstraction reactions and the stannyl radical can then abstract halogen from the alkyl group. For example, net addition of an alkyl group to a reactive double bond can follow halogen abstraction by a stannyl radical. 

This generalized reaction sequence consumes the halide, the stannane, and the reactant X=Y, and effects addition to the organic radical and a hydrogen atom to the X=Y bond. The order of reactivity of organic halides toward stannyl radicals is iodides > bromides > chlorides. 

Radicals for addition reactions can be generated by halogen atom abstraction by stannyl radicals. The chain mechanism for alkylation of alkyl halides by reaction with a substituted alkene is outlined below. There are three reactions in the propagation cycle of this chain mechanism addition, hydrogen atom abstraction, and halogen atom transfer. 

Allylic stannanes are an important class of compounds that undergo substitution reactions with alkyl radicals. The chain is propagated by elimination of the trialkyl -stannyl radical.315 The radical source must have some functional group that can be abstracted by trialkylstannyl radicals. In addition to halides, both thiono esters316 and selenides317 are reactive. 

A radical cyclization of this type was used to synthesize the 4-amino-5-hydroxyhexahydroazepine group found in the PKC inhibitor balanol. The cyclization involves an a-stannyloxy radical formed by addition of the stannyl radical to the aldehyde oxygen. 

Entry 21 involves addition to a glyoxylic hydrazone and the cis ring junction is dictated by strain effects. The primary phenylselenyl group is reductively removed under the reaction conditions. Entry 22 involves generation of a stannyloxy radical by addition of the stannyl radical at the carbonyl oxygen. Cyclization then ensues, with the cis-trans ratio being determined by the conformation of the cyclization TS. 

The fact that this reaction is stereoselective implies that the chiral triorgano-stannyl radical formed in the first step is trapped by the olefin more rapidly than it inverts. This shows the optical stability of triorganostannyl radicals, which are known to be non-planar 59) like triorganogermyl radicals 62>. 

Rate Constants of Free Radical Substitution Reactions of Flydrogen Atom, Alkyl, and Stannyl Radicals with Peroxides R" + R1OOR1 > ROR1 + R10 ... 

TABLE 8. Absolute rate constants for the addition of triethylsilyl, tri-n-butylgermyl and tri-ra-butyl-stannyl radicals to alkenes18a... 

Chlorination does not occur in the presence of hydroquinone, hence a radical process is implicated. It is inferred that the stannyl radical retains configuration en route to chloride (+)-41, which then racemizes by a dissociative process. It is estimated that racemization of chloride (+)-41 in CCI4 at 0.18 M concentration requires about 10 min at room temperature. 

The following mechanistic pathway seems to be the most plausible A single ET is followed by the cleavage of a stannyl radical which is trapped by the solvent CH2CI2, while the ene-oxonium residue is attacked by the nucleophile. Indeed, the electrolysis can be carried out with the nucleophile as solvent. 

Radical homologation. This tin pinacolate is known to generate trimethyltin radicals at 60° and appears to be superior to tributyltin hydride as a source of stannyl radicals for addition of alkyl halides to O-benzylformaldoxime (equation I).1 Iodides, bromides, and selenides can be used as radical precursors. The same... 

Homolytic hydrostannation can also be initiated at room temperature by thiophenols, when a trace of oxygen may oxidize the thiol to the ArS radical, which abstracts hydrogen from the stannane to give the stannyl radical (Equation (15)).93 With azoisobutyronitrile (AIBN) initiation, alkynes undergo only monohydrostannation, but with the thiol, simple alkynes show bis(hydrostannation) or bis(stannation). 

Most of the many applications of the tin hydrides in organic synthesis proceed by radical chain reactions in which one step involves the reaction of a radical X- with the tin hydride to abstract hydrogen and generate a stannyl radical,... 

Stannyl radicals are usually generated by homolytic substitution at hydrogen in a tin hydride, or at tin in a distannane, or, conjugatively, at the y-carbon atom in an allylstannane.453 The initiator is commonly AIBN at ca. 80 °C. In the presence of a trace of air, organoboranes are oxidized by a radical chain mechanism, and triethylborane is now commonly used as an initiator at temperatures down to —78°C,519 and it can be used in aqueous solution.520 9-Borabicyclo[3.3.1]nonane (9-BBN) has similarly been used to initiate the reaction of tin hydrides at 0 and —78°C,521 and diethylzinc works in the same way.522... 

Free-radical cyclizations using ethyl radicals generated by EtsB/air system or stannyl radicals systems provide a range of carbocyclic and heterocyclic hydroxylamines (equation 77). Stereoselectivity in these reactions is variable but can be semiquaUtatively predicted by Beckwith-Houk models . Depending on the substitution pattern of the emerging cyclic system, stereoselectivity can be very high, especially in fused polycyclic systems (equation... 

One of the most useful sources of free radicals in preparative chemistry is the reaction of halides with stannyl radical... 

Selenenyl groups can be abstracted from acyl selenides to generate radicals on reaction with stannyl radicals.201 202 203 Normally, some type of stabilization of the potential reaction site is necessary. Among the types of selenides that are generated by selenenyl abstraction are x-sclcncnyl cyanides and a-selenenyl phosphates. 

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