Vinylic substitution reactions, transition

These reactions involve metallate rearrangements , migratory insertion and transition metal-catalysed vinylic substitution reactions. They also perform well in applications in natural product synthesis . Many useful synthetic possibilities arise from application of ring-closing olefin metathesis (RCM) to unsaturated homoaldol products and their derivatives by means of the Grubbs catalyst 3942 4-286 Equation 105 presents some examples. ... 

Numerous reactions of alkenyl(phenyl)iodonium salts leading to the formation of new C-C bond have been reported in the literature. The most important and synthetically useful reactions include the generation and subsequent cyclization of alkylidenecarbenes, alkenylation of carbon substrates via nucleophilic vinylic substitution, and transition metal-mediated coupling reactions. 

These reactions involve metallate rearrangements [231], migratory insertion and transition metal-catalyzed vinylic substitution reactions. They also perform well in applications in natural product synthesis [204,205,209,233]. 

Study of structure-activity relationships in nucleophilic vinylic substitution reactions (S nV) that proceed by the addition-elimination mechanism has been furthered by the study of acid-catalysed breakdown of alkoxide and thiolate ion adducts of benzylidene Meldrum s acid (36a), methoxybenzylidene Meldrum s acid (36b), and thiomethoxybenzylidene Meldrum s acid (36c). Catalysis of alkoxide or thiolate expulsion is in competition with protonation of the a-carbon or one of the carbonyl oxygens to form an enolate. The positive Ag values for H+-catalysed RO and RS departure imply an imbalanced transition state in which proton transfer leads C-O or C-S bond cleavage. The pA values of the various adducts are much lower than for Meldrum s acid, in view of the stabilizing influence of OR, SR, and OMe groups on the carbanion. 

The use of transition metals for the facilitation of substitution reactions on vinylic carbon has proven to be quite successful. For example, vinylic chlorides in the presence of nickel(II) chloride react with trialkyl phosphites to substitute phosphorus for the halide (Figure 6.17j.71-72 While reminiscent of a direct Michaelis-Arbuzov reaction, including final dealkylation by a chloride ion, the reaction actually involves an addition-elimination process. It appears that chloride provides a more facile reaction than bromide, a characteristic noted in several reaction systems. 

Benzamido allylic acetates 242 and 243 undergo palladium-catalyzed cychza-tion to oxazolines. Excellent yields and very high diastereoselectivity is observed for the conversion of several acyclic primary and secondary benzamido aUyhc acetates to tran -5-vinyl substituted oxazolines 244. The diastereoselectivity of the reaction is determined by the the steric interactions between the R group and the hydrogen of the 7i-allylpalladium complex in the transition state, trans-Oxazolines are obtained since transition state A is favored over transition state B (Scheme 8.66). 

Nucleophilic vinylic substitutions are closely related to nucleophilic aromatic substitutions, as in both the leaving group leaves from an unsaturated carbon atom. However, the vinylic substitution routes are much more diverse, and disclose more of the details of the reaction. Stereochemical study of the reaction can give information on the lifetime of the intermediate and about the structure of the transition state... 

We get the full value when there are no nitro groups to take the brunt of the negative charge. This vinylic substitution (an unusual reaction ) has a p value of +9.0. It cannot be an S>j2 reaction or it would have a small p value and it cannot be an S>j 1 reaction or it would have a negative p value (fewer electrons in the transition state). It must be an addition-elimination mechanism through a benzylic anion delocalized round both benzene rings. 

Ionic liquids can be used as replacements for many volatile conventional solvents in chemical processes see Table A-14 in the Appendix. Because of their extraordinary properties, room temperature ionic liquids have already found application as solvents for many synthetic and catalytic reactions, for example nucleophilic substitution reactions [899], Diels-Alder cycloaddition reactions [900, 901], Friedel-Crafts alkylation and acylation reactions [902, 903], as well as palladium-catalyzed Heck vinylations of haloarenes [904]. They are also solvents of choice for homogeneous transition metal complex catalyzed hydrogenation, isomerization, and hydroformylation [905], as well as dimerization and oligomerization reactions of alkenes [906, 907]. The ions of liquid salts are often poorly coordinating, which prevents deactivation of the catalysts. 

When coordinated to palladium, the rr-indenyl ligand tends to slip from the if - to the 77 -coordination mode, and most of the complexes synthesized show severe distortions or clear -indenyl coordination. Thus, although being a cyclopentadienyl analog, it is rare to find a true Tj -indenyl coordination to palladium, however common for other transition metals. Metathesis with Li[indenide] and ligand-substitution reactions are common preparative routes for indenyl derivatives. The insertion of an alkyne into Pd-G bonds of vinyl substituted aryls, followed by intramolecular alkene insertion, also leads to highly substituted indenyl palladium complexes. Equation (66) shows one of these examples. ... 

Thus, our initial goal was to develop new synthetic procedures to allow high yield selective synthesis of vinylborazine. Since our previous work - has demonstrated that transition metal reagents, similar to those widely employed in organic and organometallic chemistry, may be used to catalyze a variety of transformations involving B—H activation reactions, we investigated the use transition metals to catalyze the alkyne-addition and olefin-substitution reactions of borazine. As a result we found, as indicated below, that B-vinyl... 

Due to sluggish reactivity of aryl and vinyl halides in nucleophiUc substitution reactions, the formation of sulfur-carbon(sp ) bonds is typically carried out using transition metal catalysis [22-27]. While the field is dominated by the use of palladium, copper, and nickel catalysts, considerable advances have been made using more abundant metal catalysts such as iron. Additionally, a number of transition metal-fiee approaches have been developed for the formation of sulfur-carbon(sp ) bonds. The following sections will highlight representative examples of C—S bond forming reactions. 

Previously, we have discussed that the inversion of the stereoehemistry in the solvolysis product of vinyl iodonium salt 2 could be explained by an in-plane S 2 vinylic substitution. The same arguments can be employed now to explain how the minor isomer 6Z is formed (Scheme 35.6). Direct attack of acetic acid to the a-carbon should lead to the observed reaction product in a one-step proeess through transition state 9. The position of the deuterium atom should not change (no scrambling), only the stereochemistry of the product has been reversed during the reaction. 

In the Lewis acid mediated reaction the developing carbenium ion in C is stabilized by the nearby 7t-electrons of the titanium or aluminum enolate. This generates as the major diastereomer the 3,3a-/r .v-relationship between the substitution at the ring junction and the vinyl group at C-3 via a synclinal transition state. 

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