Elimination reactions from carbanion

Because of thetr electron deficient nature, fluoroolefms are often nucleophihcally attacked by alcohols and alkoxides Ethers are commonly produced by these addition and addition-elimination reactions The wide availability of alcohols and fliioroolefins has established the generality of the nucleophilic addition reactions The mechanism of the addition reaction is generally believed to proceed by attack at a vinylic carbon to produce an intermediate fluorocarbanion as the rate-determining slow step The intermediate carbanion may react with a proton source to yield the saturated addition product Alternatively, the intermediate carbanion may, by elimination of P-halogen, lead to an unsaturated ether, often an enol or vinylic ether These addition and addition-elimination reactions have been previously reviewed [1, 2] The intermediate carbanions resulting from nucleophilic attack on fluoroolefins have also been trapped in situ with carbon dioxide, carbonates, and esters of fluorinated acids [3, 4, 5] (equations 1 and 2)... 

A more general method for preparing carbenes often involves the a elimination of halides from carbanions.1-57 PAC can be used to examine the rates and energetics of the reverse reactions, the complexation of halides with carbenes (Fig. 5).58 Plots of A//com versus the proton affinities (PA) of the halides are linear for the two carbenes studied. Although the slopes of the plots are similar, complexation of the halides with phenylchlorocarbene is more exothermic than phenylfluorocarbene. This indicates that fluoro substitution stabilizes the carbene relative to the carbanion more than chloro substitution. The rate of complexation of carbenes with salts has also been examined by nanosecond absorption spectroscopy.59... 

Ketones can be prepared from special carbanions types by elimination reactions which follow oxygenation. 

In some useful synthetic procedures, the carbanionic character results from a reductive process. A classical example of the -elimination reaction is the reductive debromination of vicinal dibromides. Zinc metal is the traditional reducing agent.209 A multitude of other... 

The proposed mechanism of this reaction is composed by an initial S v2-type nucleophilic substitution reaction of 113 with the nucleophilic a-sulfonyl lithium carbanion to give the alkylmagnesium species (114) having a sulfonyl group at the / -position. Then, a -elimination reaction of magnesium sulfinate from the intermediate (114) occurs... 

A practical synthesis of bicyclo[1.1.0]butane-l-carbonitrile (67) from 3-chlorocyclobutane-l-carbonitrile by treatment with potassium Ze/7-butoxide in ttvh-butyl alcohol has been reported.25 Detailed mechanistic studies have also been carried out on the elimination of hydrogen chloride from bww-3-chlorocyclobutane-l-carbonitrile (66) and cis-3-chlorocyclobutane-l-carbonitrile (68), yielding 67.26 28 It has been reported that the elimination reactions of the two isomers are likely to proceed via a common carbanion intermediate. However, in the presence of a crown ether, the carbanion intermediates derived from the trans-isomer 66 and the ds-isomer 68 are found experimentally not to be identical. These intriguing results are attributed to the presence or absence of the potassium cation in assisting the expulsion of the leaving chloride ion.26... 

Unsaturated fluorinated compounds are fundamentally different from those of hydrocarbon chemistry. Whereas conventional alkenes are electron rich at the double bond, fluoroal-kenes suffer from a deficiency of electrons due to the negative inductive effect. Therefore, fluoroalkenes react smoothly in a very typical way with oxygen, sulfur, nitrogen and carbon nucleophiles.31 Usually, the reaction path of the addition or addition-elimination reaction goes through an intermediate carbanion. The reaction conditions decide whether the product is saturated or unsaturated and if vinylic or allylic substitution is required. Highly branched fluoroalkenes, obtained from the fluoride-initiated ionic oligomerization of tetrafluoroethene or hexafluoropropene, are different and more complex in their reactions and reactivities. 

From this, it can be seen that the amount of KOH within the hydroxide mixture would probably be critical in removing organo-sulfur from coal. While the particular role of KOH has not been determined, evidence from the literature has shown that the size of the cation may be important in stabilizing intermediate carbanions. Wallace et al. (J ) conducted a series of base- catalyzed, beta-elimination reactions with isopropyl sulfide and measured the amount of olefin production. The proposed mechanism involved initial abstraction of a proton by the t-butoxide base, and formation of a carbanion, with subsequent elimination of the sulfur moiety (which can be considered a good leaving group) to form the olefin (Equation 5). 

Having shown that general-base-catalyzed carbanion formation precedes the oxidation step in flavin oxidation of the second class of carbon acids, the question arises as to how the electron pair moves from the carbanion to flavin. Covalent addition of carbanion to Flox followed by a base-catalyzed elimination reaction is one possibility (13). Addition to the 4a- (Equation 17) and 5-position (Equation 18) would appear to be feasible and, a priori, it would seem reasonable to expect that these adducts could undergo an elimination to yield oxidized substrate and reduced flavin. Nucleophilic addition of SO J to... 

The pair of unshared electrons on the carbanion can undergo two reactions (a) it can recombine with a proton from the solvent to regenerate either the original amino acid side chain or its optical antipode, so that it is racemized (b) it can undergo the indicated 6-elimination reaction to form a dehydroalanine derivative, which can then combine with an e-amino group of a lysine side chain to form a lysinoalanine crosslink. 

The formation of III and IV can both be understood as a series of addition-elimination reactions occurring on the central C=C bond of I, by the works of sulfur anions liberated by the interaction of o-benzodithiol (II) and trimethyl-amine. However, the direction of the addition reaction cannot be ascertained at first glance, because some confusion may occur if the relative stability of the carbanions resulting from this operation is not carefully analyzed first. For this purpose, there are the handy Baldwin s Rules, although these laws face some problems when applied to second-row elements such as sulfur. Therefore, they will be disregarded here. 

As mentioned in the previous section, the Peterson reaction proceeds by an irreversible addition of the silyl-substituted carbanion to a carbonyl. It has generally been assumed that an intermediate p-oxidosi-lane is formed and then eliminated. In support of this mechanistic hypothesis, if an anion-stabilizing group is not present in the silyl anion, the p-hydroxysilanes can be isolated fixrm the reaction, and elimination to the alkene carried out in a separate step. Recent studies by Hudrlik indicate that, in analogy to the Wittig reaction, an oxasiletane (304) may be formed directly by simultaneous C—C and Si—O bond formation (Scheme 43). The p-hyd xysilanes were synthesized by addition to the silyl epoxide. When the base-induced elimination was carried out, dramatically different ratios of cis- to rranr-alkenes were obtained than from the direct Peterson alkenation. While conclusions of the mechanism in general await further study, the Peterson alkenation may prove to be more closely allied with the Wittig reaction than with -elimination reactions. 

The intermediate of the ElcB mechanism is a carbanion, and thus any factors that stabilise such an ion should favour this mechanism. We have already noted above that on the face of it, elimination reactions are the reverse of addition reactions. However, we also noted that the actual mechanistic pathways involved in elimination reactions were more similar to substitution reactions than addition reactions. This is because normally elimination reactions proceed via a carbonium ion or in a single step that has certain similarities to an SN2 substitution reaction. However, there are also addition reactions that proceed via a carbanion intermediate, for example the Michael-type reaction, in which a carbanion adds to an a,(3-unsaturated carbonyl compound. Indicate the Michael-type addition between the anion formed from the diester of propandioic acid (or malonic acid) and 2-butenal. 

Among the ethers of prolinol, (5)-2-methoxymethylpyrrolidinc [SMP, (S)-10] has found most applications. It is readily prepared from prolinol by the normal sodium hydride/iodo-methane technique9,13 (sec also Section 2.3. for O-alkylations of other amino alcohols) and is also commercially available. An improved synthesis from proline avoids the isolation of intermediates and gives the product (which is highly soluble in water) by continuous extraction14. SMP has been used as the lithium salt in deprotonation and elimination reactions (Section C.) and as an auxiliary for the formation of chiral amides with carboxylic acids, which in turn can undergo carbanionic reactions (Sections D.l.3.1.4., D.l. 1.1.2.. D.l. 1.1.3.1., in the latter experimental procedures for the formation of amides can be found). Other important derivatives are the enamines of SMP which are frequently used for further alkylation reactions via enolates (Sections D.l.1.2.2.. where experimental procedures for the formation of enamines are... 

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