Allyl electronic effect

Entries 6 to 8 demonstrate addition of allyl trimethylsilane to protected carbohydrate acetals. This reaction can be a valuable method for incorporating the chirality of carbohydrates into longer carbon chains. In cases involving cyclic acetals, reactions occur through oxonium ions and the stereochemistry is governed by steric and stereo-electronic effects of the ring. Note that Entry 8 involves the use of trimethylsilyl... 

The rationalization of stereoselectivity is based on two assumptions. (1) The 1-arylthio-1-nitroalkenes adopt a reactive conformation in which the ally lie hydrogen occupies the inside position, minimizing 1,3-allylic strain. (2) The epoxidation reagent can then either coordinate to the ally lie oxygen (in the case of Li), which results in preferential syn epoxidation or in the absence of appropriate cation capable of strong coordination (in the case of K) steric and electronic effects play a large part, which results in preferential anti epoxidation (Scheme 4.7).52... 

The regioselectivity in palladium-catalyzed alkylations has been attributed to the dynamic behavior of trihapto pentadienyl metal complexes60. For example, competing electronic and steric effects influence product formation in dienyl epoxides, but in palladium-catalyzed reactions steric factors were often found to be more important. Thus, alkylation of dienyl epoxide 76 with bulky nucleophiles such as bis(benzenesulfonyl)me-thane in the presence of (Ph3P)4Pd occurred exclusively at the terminal carbon of the dienyl system producing allyl alcohol 77 (equation 39). However, the steric factors could be overcome by electronic effects when one of the terminal vinylic protons was replaced with an electron-withdrawing group. Thus, alkylation of dienyl epoxide 78 affords homoal-lylic alcohol 79 as the major product (equation 40). 

The allyl cation thus formed may stabilize itself either by readdition of the leaving group — leading to a 2,3-dihalopropene — or by the addition of a nucleophile. The influences of steric and electronic effects on the stereochemistry and on the solvolysis rates of various alkyl-substituted chlorocyclopropanes have been investigated by Parham and co-workers [165, 166], who could show for example that os-2,3-dipropyl-l,l-dichlorocyclopropane solvolyzes 24 times faster than its trans-isomer, in accordance with predictions based on orbital symmetry arguments. When one propyl substituent of the trans-isomer is replaced by an ethoxy group the rate of solvolysis increases 200 fold. 

SCHEME 67. Steric and electronic effects in the diastereoselective catalytic epoxidation of cyclic olefins and allylic alcohols with MTO/UHP... 

An additional issue of regiocontrol arises in asymmetric induction when the n-allyl complex possesses a primary terminus. Although steric factors favor the formation of the achiral linear product, alkylations with reactive nucleophiles often benefit from electronic effects leading to the branched product [ 147,148]. Of particular interest is the reaction of the crotyl system because... 

Recent developments in the stereoselective singlet oxygen allylic photo-oxygenations of alkenes have been reviewed. A number of factors, such as solvent, electronic effects, and non-bonded interactions that dictate the ene product selectivity, and also the various mechanisms of this reaction, have been highlighted.239... 

Intramolecular hydroboration of allyl vinyl ethers.1 The hydroboration and subsequent oxidation of allyl vinyl ethers 1 with ThxBH2 (2 equiv.) leads to 1,3-diols with almost exclusive syn selectivity. High syn selectivity obtains regardless of the bulk of R1, but is lowered when R is phenyl. Apparently, electronic effects of R1 are important for stereoselectivity. 

Donor/acceptor-substituted carbenoids are usually much more chemoselective than the more established carbenoids functionalized solely with acceptor groups [lc]. The development of these donor/acceptor-substituted carbenoids has enabled enantioselective intermolecular C-H insertions to become a very practical process. These carbenoids have a strong preference for functionalizing C-H bonds where positive charge build-up at C in the transition state is favored but these electronic effects are counter-balanced by steric factors. Benzylic and allylic sites and C-H bonds adjacent to oxygen and nitrogen functionality are favored but these sites can also be sterically protected if desired. By appropriate consideration of the regiocontrolling elements, effective intermolecular C-H insertions at methyl, methylene, and methine sites have been achieved. 

The Pd(0)-catalyzed allylation of 96 with acrolein dimethyl acetal gives exclusively compound 104. The 7j3-allylpalladium cationic complex (4, R = OMe) is attacked only at the center bearing the substituent MeO (80SC147), thus emphasizing the importance not only of steric effects in the electrophile but also of the electronic effects in the Tsuji-Trost reaction (92T1695). Indole 96 has been also allylated with epoxide 105 under Pd(0) catalysis by Trost and Molander (81JA5969). The intermediate cationic complex is attacked at the exocyclic position, 106 being formed, as shown in Scheme 22. 

Table 7.2 Electronic effects in the allylation of p-substituted benz-aldehydes la-c with 2a, catalyzed by pyridine N-oxides 22 and 24 at -40 °C (Scheme 7.1 and Fig. 7.2) [28-30].

The formation of the dioxolanes in the photo-oxygenations of allylic stannanes with electron rich tin centers (i.e., compare 16 and 20) can be attributed to the ability of tin to stabilize and migrate to an electron deficient P carbon (Sch. 9). The reduced yield of dioxolane in the reaction of 22 in comparison to 20 or 21 can be attributed to a steric effect operating in conjunction with an electronic effect of the carbomethoxy group in the bridged (or perhaps open) intermediate 23 which promotes hydrogen abstraction in lieu of sterically more demanding nucleophilic attack (Sch. 9). 

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