Elimination from alkoxides

The vertical electron affinity (EA) of acetone is given as —1.51 eV by Jordan and Burrow386. Lifshitz, Wu and Tiernan387 determine—among other compounds—the excitation function and rate constants of the slow proton transfer reactions between acclone-Ih, acetone-Dg and other ketones. The acetone enolate anion has been produced in a CO2 laser induced alkane elimination from alkoxide anions by Brauman and collaborators388-390. These show, e.g. that the methane elimination from t-butoxide anion is a stepwise process ... 

Alkoxides. y6-H elimination from alkoxides is responsible for the reducing properties of alcohols towards some transition metal complexes, particularly in the presence of base. The formation of a metal alkoxide followed by /1-H elimination affords a hydride. Decoordination of the aldehyde and HX elimination, if the hydride is unstable, will reduce the oxidation state of the complex in two units, often leading to decomposition products (Scheme 6.27). 

Besides direct hydrolysis, heterometaHic oxoalkoxides may be produced by ester elimination from a mixture of a metal alkoxide and the acetate of another metal. In addition to their use in the preparation of ceramic materials, bimetallic oxoalkoxides having the general formula (RO) MOM OM(OR) where M is Ti or Al, is a bivalent metal (such as Mn, Co, Ni, and Zn), is 3 or 4, and R is Pr or Bu, are being evaluated as catalysts for polymerization of heterocychc monomers, such as lactones, oxiranes, and epoxides. An excellent review of metal oxoalkoxides has been pubUshed (571). 

Together with a shift of the proton from the a-carbon to the alkoxide oxygen, the tertiary amine is eliminated from the addition product to yield the unsaturated product 3. Early examples of the Baylis-Hillman reaction posed the problem of low conversions and slow reaction kinetics, which could not be improved with the use of simple tertiary amines. The search for catalytically active substances led to more properly adjusted, often highly specific compounds, with shorter reaction times." Suitable catalysts are, for example, the nucleophilic, sterically less hindered bases diazabicyclo[2.2.2]octane (DABCO) 6, quinuclidin-3-one 7 and quinuclidin-3-ol (3-QDL) 8. The latter compound can stabilize the zwitterionic intermediate through hydrogen bonding. ... 

It should be mentioned here that if no other leaving group is present, sulfonyl can act as its own leaving group in hydroxide- or alkoxide-catalyzed elimination from sulfones. Carbanion formation is not involved in this but the promotion of the ionization of a C—H bond by the sulfonyl group is seen at the /1-carbon rather than the a-carbon, e.g. equation 21. 

The hydrido(ethoxo) complex carrying an electron-donating q -CsMes (= Cp ) ligand, [Cp IrH(OEt)(PPh3)] (4), was prepared by a metathesis reaction between [Cp Ir Cl2(PR3)] (3) and NaOEt followed by P-H elimination from the intermediate diethox-ide complex (Eq. 6.4) [7]. Several other iridium alkoxide analogs [Cp IrH(OR)... 

The catalytic cycles that have been documented, namely alkyne eyelotrimerization and olefin isomerization, demonstrate that addition and elimination from dimetal centers can occur readily in the presence of metal-metal bonds and alkoxide 1igands. 

Scheme 3.7 Generation of the active hydride catalyst by hydrogen transfer from formic acid or iso-propanol via /5-hydride elimination from formate or alkoxide intermediates. The square represents a vacant site on ruthenium.

The elimination from the zirconium alkoxide B (Scheme 8.23) to give the 1,4-diene also proceeds through cationic activation. An independently prepared sample of pure B (X = Cl) would not undergo elimination unless a catalytic amount of AgC104 (or TMSC104, which is the probable chain carrier in this elimination reaction) was added. If AgAsF6 is used as the promoter for the reaction sequence, only the first (addition) step takes place and no elimination to the diene is observed [51],... 

The mechanism of reversible (5-hydrogen elimination from square planar lr(l) alkoxide complexes with labile dative ligands, followed by associahve displacement of the coordinated ketone or aldehyde by incoming phosphine, which can be implied in TH reactions, was proposed by Hartwig and coworkers [36]. 

Thiols very readily add to diacetylene in the presence of bases, such as alkoxides, with formation of enyne sulfides HC=CCH=CHSR [175]. In strongly basic media, thiol can be eliminated from these enyne derivatives [2], Thus, functionalization of HChCCH=CHSR followed by treatment with an excess of sodium amide results in a derivative of butadiyne. This sequence of conversions permits the synthesis of some 1,3-diyne systems that are not otherwise easily accessible. 

General methods for the preparation of a.jS-unsaturated iron-acyl complexes are deferred to Section D 1.3.4.2.5.1.1. examples of the alkylation of enolates prepared via Michael additions to ii-0 ,/ -unsaturated complexes prepared in situ are included here. Typical reaction conditions for these one-pot processes involve the presence of an excess of alkyllithium or lithium amide which first acts as base to promote elimination of alkoxide from a /f-alkoxy complex to generate the -a,)S-unsaturated complex which then suffers 1,4-nucleophilic addition by another molecule of alkyllithium or lithium amide. The resulting enolate species is then quenched with an electrophile in the usual fashion. The following table details the use of butyllithium and lithium benzylamide for these processes44,46. 

Alcohols can also be prepared from support-bound carbon nucleophiles and carbonyl compounds (Table 7.4). Few examples have been reported of the a-alkylation of resin-bound esters with aldehydes or ketones. This reaction is complicated by the thermal instability of some ester enolates, which can undergo elimination of alkoxide to yield ketenes. Traces of water or alcohols can, furthermore, lead to saponification or transesterification and release of the substrate into solution. Less prone to base-induced cleavage are support-bound imides (Entry 2, Table 7.4 see also Entry 3, Table 13.8 [42]). Alternatively, support-bound thiol esters can be converted into stable silyl ketene acetals, which react with aldehydes under Lewis-acid catalysis (Entries 3 and 4, Table 7.4). 

Vinyl ethers have also been prepared by addition of alkoxides to acetylene,6 7 6 elimination from halo ethers and related precursors,6 8 and vinyl exchange reactions.6 Reaction of an electrophilic tungsten carbenoid with methylene phosphorane or diazomethane also produces vinyl ethers.9 Enol ethers have resulted from the reaction of some tantalum and niobium carbenoids with esters,10 and the reaction of phosphoranes with electrophilic esters.4... 

The other feature that enriches but also complicates the chemistry of rhenium alkoxides is their ability to use different kinds of decomposition processes, not leading to the changes in the oxidation state. That is first and foremost the ether elimination from the rhenium (V-VII) derivatives. It leads to the formation of oxocomplexes, as, for example [168] ... 

Interestingly, cyclopropane 245 (R = SPh) is also formed when 243 is combined with (trimethylsilyl)oxirane. In this case, the necessary alkene (phenylthioethylene) is provided by silanolate elimination from the alkoxide arising from regiospecific ring-opening of the oxirane by thiophenolate (equation 82)142. 

Mann, G. Hartwig, J. F. Palladium alkoxides potential intermediacy in catalytic animation, reductive elimination of ethers, and catalytic etheration. Comments on alcohol elimination from Ir(III)./. Am. Chem. Soc. 1996, 118, 13109-13110. 

Although collision induced dissociation (CID) is a well-known method for investigating the structures of cations in the gas phase (McLafferty, 1983), it has been applied much less to anions (Bowie, 1986). Actually, in some cases CID has been used to study the fragmentation mechanisms of anions, such as the elimination of molecular hydrogen from alkoxide ions (Hayes el al., 1984) or the primary fragmentation routes of ester enolate ions (Froelicher et al., 1985). 

Due to the same compulsory anti-selectivity the potassium alkoxide-mediated HBr eliminations from trans-1,2-dibromocy clohexane ultimately results in the formation of 1,3-cyclohexa-diene rather than 1-bromocyclohexene (Figure 4.25). The reason is that an anh -selective elimination occurs initially, trans-1,2-Dibromocyclohexane—except in very polar solvents— prefers a chair conformation with axial C-Br bonds (as it is only in this conformation that the... 

The intramolecular nudeophilic substitution reaction - for example, the William-son-type reaction - represents one of the important methods for preparing oxetane ring structures, and have been widely applied to the synthesis of oxetanes (Scheme 7.1) [10]. Unfortunately, side reactions - which indude fragmentation from the intermediary alkoxide anion or elimination from the intermediary carboca-tion - often decrease the chemical yields of oxetane formation. 

Hydroxide and alkoxide anions are strong enough bases to promote a elimination from chloroform, and from other trihalomethanes. Carbenes can be formed from dihaloalkanes by deprotonation with stronger bases such as LDA, and even from primary alkyl chlorides using the extremely powerful bases phenylsodium or f-BuLi/f-BuOK (weaker bases just cause P elimination). 

In aerobic oxidations of alcohols a third pathway is possible with late transition metal ions, particularly those of Group VIII elements. The key step involves dehydrogenation of the alcohol, via -hydride elimination from the metal alkoxide to form a metal hydride (see Fig. 4.57). This constitutes a commonly employed method for the synthesis of such metal hydrides. The reaction is often base-catalyzed which explains the use of bases as cocatalysts in these systems. In the catalytic cycle the hydridometal species is reoxidized by 02, possibly via insertion into the M-H bond and formation of H202. Alternatively, an al-koxymetal species can afford a proton and the reduced form of the catalyst, either directly or via the intermediacy of a hydridometal species (see Fig. 4.57). Examples of metal ions that operate via this pathway are Pd(II), Ru(III) and Rh(III). We note the close similarity of the -hydride elimination step in this pathway to the analogous step in the oxometal pathway (see Fig. 4.56). Some metals, e.g. ruthenium, can operate via both pathways and it is often difficult to distinguish between the two. 

One of the main questions in the cobalt(III)-promoted hydrolysis of activated amino acid esters is whether the ratedetermining step is addition of hydroxide to the carbonyl carbon, or loss of the alkoxide from the intermediate. Work with /3-alanine ester showed that below pH 8.5 the ratedetermining step was the elimination of alkoxide. At pH 10 and above, the rate-determining step changes and the addition of hydroxide to the activated ester becomes the rate-controlling step. This is due to the fact that above pH 10 the hydroxyl group of the intermediate becomes deprotonated (equation 7). The deprotonation of the hydroxyl group accelerates the loss of alkoxide by 10 times. ... 

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