Alkenes substituent

Overall the stereospecificity of this method is the same as that observed m per oxy acid oxidation of alkenes Substituents that are cis to each other m the alkene remain CIS m the epoxide This is because formation of the bromohydrm involves anti addition and the ensuing intramolecular nucleophilic substitution reaction takes place with mver Sion of configuration at the carbon that bears the halide leaving group... 

M-Acyliminium cyclizations of optically active mono- and di-oxygenated hydroxylactam derivatives have been used in the synthesis of a number of natural products. In case of a five-membered lactam the oxygen function adjacent to the iminium carbon directs attack of the internal nucleophile from the least hindered side, opposite to the substituent. In the examples given the size of the newly formed ring is determined by the electronic bias of the alkene substituent. 

The Arrhenius frequency factors [log(T/M V)] for addition of carbon centered radicals to the unsubstiUited terminus of monosubslituted or 1,1-disubstituted olefins cover a limited range (6.0-9.0), depend primarily on the steric demand of the attacking radical and are generally unaffected by remote alkene substituents. Typical values of log(T/M" V) are ca 6.5 for tertiary polymeric (e.g. PMMA ), ca 7.0 for secondary polymeric (PS, PMA, and ca 7.5, 8.0 and 8.5 for small tertiary (e.g. /-C4H9 ), secondary (i-CiH ) and primary (CHj, CbHs ) radicals respectively (Section 4.5.4).4 For 1,2,2-trisubstituted alkenes the frequency factors arc about an order of magnitude lower.4 The trend in values is consistent with expectation based on Iheoretical calculations. 

The stereochemistry of the resulting cyclopropane product (.s vn vs anti) was rationalized from a kinetic study which implicated an early transition state with no detectable intermediates. Approach of the alkene substrate perpendicular to the proposed carbene intermediate occurs with the largest alkene substituent opposite the carbene ester group. This is followed by rotation of the alkene as the new C—C bonds begin to form. The steric effect of the alkene substituent determines... 

Absolute rates have been measured for some carbene reactions. The rate of addition of phenylchlorocarbene shows a small dependence on alkene substituents, but as expected for a very reactive species, the range of reactivity is quite narrow.119 The rates are comparable to moderately fast bimolecular addition reactions of radicals (see Part A, Table 11.3). 

The 1-arenesulfonylprolinate catalysts have been studied computationally.209 A computed TS and conceptual model that is consistent with experimentally observed enantioselectivity is shown in Figure 10.11. The arenesulfonyl groups block one of the directions of approach to the carbene catalyst and also orient the alkene substituent away from the metal center. 

This type of indole synthesis can be elaborated to provide a viable route to oxindoles but the type of product is dependent upon the alkene substituent and the reaction solvent 74 (Schemes 45 and 46). Assuming that a mechanism... 

Stratakis, M., Nencka, R., Rabalakos, C., Adam, W. and Krebs, O. (2002). Thionin-sensitized intrazeolite photooxygenation of trisubstituted alkenes substituent effects on the regioselectivity as probed through isotopic labeling. J. Org. Chem. 67, 8758-8763... 

When 114 is treated with a variety of alkene substrates, facile insertion into the aza-zirconacycle takes place (—> 115). The derived azazirconacyclopentanes are formed with various, but generally high, levels of diastereoselection, depending on the nature of alkene substituents. As illustrated in Scheme 6.36, the non-racemic (ebthi)Zr(r 2-pyridyl)+ complex has been shown to participate in an asymmetric and catalytic C—C bond-forming reaction. 

The intramolecular cyclization of oximes with alkene substituents to dihydropyrroles in the presence of radical initiator or by heating was also describedThus, oxime 83 underwent a tandem 1,2-prototropy-cycloaddition sequence and gave an unstable cycloadduct 84, which on treatment with NaOH afforded indolizine 85 (equation 36). ... 

Chlorotrifluoroethene (15) undergoes cycloadditions regiospecifically giving head-to-head cy-clobutancs. The yields of cycloaddition products depend on the nature of the alkene substituents and the stabilization of the 1,4-diradical intermediate.23-24... 

The stereochemistry of ketene to alkcne cycloadditions is such that retention of the alkene configuration is observed. Furthermore, in cycloadditions with unsymmetrically substituted ketenes the larger of the two ketene substituents ends up as with respect to the adjacent alkene substituent (or eiulo in cycloalkene cycloadditions). This stereochemical outcome was originally attributed to the concerted [ff2a + n2a] nature of kctcnc to alkene cycloadditions,21 although more recent experimental and theoretical evidence indicate that these reactions are asynchronous and in some cases in which polarized double bonds are involved actual zwittcrions may be intermediates.9 1195 Also in certain cases the endo product in ketene to alkene cycloadditions may be the thermodynamic product from equilibration studies.22,23 Nevertheless, stereochemical control can be achieved in most such reactions as shown by the examples of 12,24 13,29 14,25 15,26 16,27 and 17.28... 

In another model, the stereoselectivity is predetermined by steric interactions between the metal and/or its ligands and alkene substituents arising during the olefin coordination to the metallocarbene.91 These steric factors govern the orientation of alkene approaching the metallocarbene in a way to minimize alkyl-ligand repulsion. Compounds 5 and 6 depict favored cis-cis and trans-trans orientations, respectively. 

Another useful reaction exemplified for the spirophosphorane (185), which is in equilibrium with the phosphorus compound (186 P-CN = 3), is the addition of alkynes. This gives a phosphorane with an alkene substituent (187 Scheme 30) (80TL925). 

Stereocontrol in intermolecular cyclopropanation also depends on the structure of the unsaturated substrate. Early work concerning the influence of substrate on stereoselectivity has been summarized by Doyle2. In general, cyclopropanation of ciy-disubstituted alkenes results in higher stereoselectivity than with monosubstituted alkenes and the steric bulk of the olefinic substituent enhances the stereoselectivity. However, the stereocontrol appears not simply to be caused by a steric factor. In comparable cases, the presence of halogen as an alkene substituent may cause a reversal of the normal stereoselectivity. A few examples which illustrate these effects are shown in equations 124167 172, 74. 

Steric effects similar to those shown in equations (39) and (40) are found when the substitution pattern leads to tetrahydropyran systems through 6-endo cyclization. Cyclizations of systems with an allylic oxygen and a syn alkene substituent give products rationalized by cyclization through H-in-plane conformations as shown earlier in equations (31) and (32).105 128 Examples with allylic methyl substitution have been reported also.1040... 

All of these decelerating effects are easily overridden by appropriate alkene substitution. Indeed, any terminal alkene substituent will decelerate 6-endo cyclization. To accelerate S-exo cyclization, one requires only an electronegative alkene substituent at C-6. 

Iodocarbonyls are excellent substrates for atom transfer cyclization, as shown by examples from our recent work in Scheme 29.19-129 When two carbonyl (or cyano) groups are present, bromides can also serve as radical precursors. Photolysis with 10% ditin usually provides excellent yields of kinetic products at high concentration, and alkene substituents often dictate the regioselectivity. The y-iodo ester products are particularly versatile for subsequent transformations, which can often be conducted in situ. Although tertiary iodine products sometimes go on to give lactones or alkenes, primary and secondary iodides can often be isolated if desired. The last example is particularly noteworthy the kinetic product from the cyclization presented in Scheme 27 is trapped, because bromine atom transfer is much more rapid that reverse cyclization. 

Kinetics is used to investigate mechanisms of radical additions to alkenes. Outside the solvent cage, the initiator-derived radicals may undergo the desired bimolecular reaction with the substrate, or side reactions. When the substrate is an alkene, the exothermic intermolecular addition of the reactive radical (R ) to the double bond results in the formation of two new single carbon-carbon bonds in place of the double bond. This reaction represents conversion of an initiator into a propagating radical in radical polymerisations, and is becoming increasingly important in a number of synthetically useful intermolecular small molecule reactions. The addition of R to monosubstituted and 1,1-disubstituted alkenes is nearly always at the unsubstituted carbon atom (tail addition), and thus is normally not affected by the individual steric demand of the alkene substituents. Equation 10.4 is the expression for the rate of addition (R ) of R to an alkene where [M] is the monomeric alkene concentration ... 

With regard to stereoselectivity, Houk observes that the endo-ortho approach is destabilized by secondary antibonding orbital interactions between the alkene substituents and the secondary positions of the benzene. 

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