Transition states vinylic substitution

A highly successful route to stereoisomers of substituted 3-cyclohexene-l-carboxylates runs via Ireland-Claisen rearrangements of silyl enolates of oj-vinyl lactones. The rearrangement proceeds stereospeaifically through the only possible boat-like transition state, in which the connecting carbon atoms come close enough (S. Danishefsky, 1980 see also section 4.8.3, M. Nakatsuka, 1990). 

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. 

The addition reactions of alkyllithium-lithium bromide complexes to a-trimethylsilyl vinyl sulfones that have as a chiral auxiliary a y-mono-thioacetal moiety derived from ( + )-camphor are highly diastereoselective. A transition state that involves chelation of the organolithium reagent to the oxygen of the thioacetal moiety has been invoked. The adducts are readily converted via hydrolysis, to chiral a-substituted aldehydes22. 

Two reasons may be offered for the enhanced /3-deuterium isotope effect in vinyl cations as compared with carbonium ions (193). As pointed out by Noyce and Schiavelli (21), in the transition state of a vinyl cation, the isotopically substituted C—H bond is ideally suited for overlap with the developing vacant p orbital, as the dihedral angle between the empty p orbital and C—H bonds is zero in the intermediate, as shown in structure 239. Shiner and co-workers (195)... 

For the addition of ethylene, EtOAc as solvent was particularly advantageous and gave 418 in 60% yield (Scheme 6.86). The monosubstituted ethylenes 1-hexene, vinylcyclohexane, allyltrimethylsilane, allyl alcohol, ethyl vinyl ether, vinyl acetate and N-vinyl-2-pyrrolidone furnished [2 + 2]-cycloadducts of the type 419 in yields of 54—100%. Mixtures of [2 + 2]-cycloadducts of the types 419 and 420 were formed with vinylcyclopropane, styrene and derivatives substituted at the phenyl group, acrylonitrile, methyl acrylate and phenyl vinyl thioether (yields of 56-76%), in which the diastereomers 419 predominated up to a ratio of 2.5 1 except in the case of the styrenes, where this ratio was 1 1. The Hammett p value for the addition of the styrenes to 417 turned out to be -0.54, suggesting that there is little charge separation in the transition state [155]. In the case of 6, the p value was determined as +0.79 (see Section 6.3.1) and indicates a slight polarization in the opposite direction. This astounding variety of substrates for 417 is contrasted by only a few monosubstituted ethylenes whose addition products with 417 could not be observed or were formed in only small amounts phenyl vinyl ether, vinyl bromide, (perfluorobutyl)-ethylene, phenyl vinyl sulfoxide and sulfone, methyl vinyl ketone and the vinylpyri-dines. 

The electron-transfer-induced cyclization of homochrysanthemol proceeds via a flve-membered transition state, from intramolecular substitution at the quaternary cyclopropane carbon, to generate the flve-membered cyclic ethers (69) and (70). In contrast, the intramolecular photo-induced cyclization of chrysanthemol goes via a six-membered transition state involving attack at the terminal vinyl carbon. 

Nucleophilic additions of ethyl-, vinyl-, and ethynyl-lithium and Grignard reagents to a 2-alkyl-substituted cycloheptanone have been found to yield the corresponding cw-cycloheptanol preferentially. The selectivity, which increases with size of the nucleophile, has been attributed to a combination of steric repulsions and torsional effects in the transition state. Application of the MM2 force field to analyse nucleophilic attack of hydride and ethynyl lithium on 2-methylcycloheptanone gave results comparable to those obtained experimentally and from ab initio calculations. 

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). 

Oxazoline formation from 5-vinyloxazolidinones promoted by palladium (0) is also known. Oxidative insertion of palladium with loss of CO2 results in a pair of equihbrating 71-allyl palladium complexes. The stereochemistry of the vinyl group is therefore not important. Ring closure from the thermodynamically more stable transition state accounts for the trans-isomer as the major product. Depending on the exact substitution, diastereoselectivities ranging from 2.5 1 to 16 1 can be obtained (Scheme 8.68). 

If the allylic system is substituted, several isomeric products can be formed. Assuming a chair-like transition state, the stereochemical outcome of a metallo-Claisen rearrangement is controlled by the geometries of the vinyl and allyl moieties, so that, if the vinyl part 68 is stereochemically pure, three different products, syn/anti-73 or 74, can be formed, depending on the exact nature of the active allylic part 72 (Scheme 6)38. 

The substitution of a trifluoromethyl group at C4 in ether 57 (substitution at position 1 on the allyl fragment) leads to no rate acceleration in comparison with allyl vinyl ether, which is in sharp contrast with a 3.5 kcal moP 1 lower Ea for the C4 cyano compound. This indicates that it is not the electron-withdrawing capacity of the substituent at C4, but its ability to stabilize radical character, which is important in stabilizing the transition state/ ... 

---