Substituent effects alkene carbons

Substituent effects (substituent increments) tabulated in more detail in the literature demonstrate that C chemical shifts of individual carbon nuclei in alkenes and aromatic as well as heteroaromatic compounds can be predicted approximately by means of mesomeric effects (resonance effects). Thus, an electron donor substituent D [D = OC//j, SC//j, N(C//j)2] attached to a C=C double bond shields the (l-C atom and the -proton (+M effect, smaller shift), whereas the a-position is deshielded (larger shift) as a result of substituent electronegativity (-/ effect). 

Hydroboration is highly regioselective and stereospecific. The boron becomes bonded primarily to the less-substituted carbon atom of the alkene. A combination of steric and electronic effects works to favor this orientation. Borane is an electrophilic reagent. The reaction with substituted styrenes exhibits a weakly negative p value (-0.5).156 Compared with bromination (p+ = -4.3),157 this is a small substituent effect, but it does favor addition of the electrophilic boron at the less-substituted end of the double bond. In contrast to the case of addition of protic acids to alkenes, it is the boron, not the hydrogen, that is the more electrophilic atom. This electronic effect is reinforced by steric factors. Hydroboration is usually done under conditions in which the borane eventually reacts with three alkene molecules to give a trialkylborane. The... 

The old and lasting problem of heterogeneous catalysis, the mechanism of alkene hydrogenation, has also been approached from the viewpoint of structure effects on rate. In 1925, Lebedev and co-workers (80) had already noted that the velocity of the hydrogenation of the C=C bond decreases with the number of substituents on both carbon atoms. The same conclusion can be drawn from the narrower series of alkenes studied by Schuster (8J) (series 52 in Table IV). Recently authors have tried to analyze this influence of substituents in a more detailed way, in order to find out whether the change in rate is caused by polar or steric effects and whether the substituents affect mostly the adsorptivity of the unsaturated compounds or the reaetivity of the adsorbed species. Linear relationships have been used for quantitative treatment. 

Substituent effects on cyclizations of simple nucleophilic hexenyl radicals have been well studied, and much quantitative rate data is available.12 The trends that emerge from this data can often be translated to qualitative predictions in more complex settings. Once the large preference for S-exo cyclization is understood, other substituent effects can often be interpreted in the same terms as for addition reactions. For example, electronegative substituents activate the alkene towards attack, and alkyl substituents retard attack at the carbon that bears them. The simple hexenyl radical provides a useful dividing point = 2 x 10s s-1. More rapid cyclizations are easily conducted by many methods, but slower cyclizations may cause difficulties. Like the hexenyl radical, most substituted analogs undergo irreversible S-exo closure as the predominate path. However, important examples of kinetic 6-endo closure and reversible cyclization will be presented. 

Abstract The main computational studies on the formation of (3-lactams through [2+2] cycloadditions published during 1992-2008 are reported with special emphasis on the mechanistic and selectivity aspects of these reactions. Disconnection of the N1-C2 and C3-C4 bonds of the azetidin-2-one ring leads to the reaction between ketenes and imines. Computational and experimental results point to a stepwise mechanism for this reaction. The first step consists of a nucleophilic attack of the iminic nitrogen on the sp-hybridized carbon atom of the ketene. The zwitterionic intermediate thus formed yields the corresponding (3-1 actant by means of a four-electron conrotatoty electrocyclization. The steroecontrol and the periselectivity of the reaction support this two-step mechanism. The [2+2] cycloaddition between isocyanates and alkenes takes place via a concerted (but asynchronous) mechanism that can be interpreted in terms of a [n2s + (n2s + n2s)] interaction between both reactants. Both the regio and the stereochemistry observed are compatible with this computational model. However, the combination of solvent and substituent effects can result in a stepwise mechanism. 

Radical stabilization energies for a wide variety of carbon-centered radicals have been calculated at G3(MP2)-RAD or better level. While the interpretation of these values as the result of substituent effects on radical stability is not without problems, the use of these values in rationalizing radical reactions is straight forward. This is not only true for reactions involving hydrogen atom transfer steps but also for other reactions involving typical elementary reactions such as the addition to alkene double bonds and thiocarbonyl compounds. 

Selective oxidation of styrene to acetophenone by a Pd(II) catalyst in the presence of ionic liquids has been achieved (equation 27). Electronic effects on the site ofPd(II) oxidation of substituted styrenes are indicated in equation (28). Strong pi-donation from the phenyl substituent favors oxidation at the alkene carbon alpha to the aromatic ring. 

The sp- carbon atoms of alkenes substituted only by allQ l groups, absorb in the range of about 110-150 ppm downfield from TMS. The double bond has a rather small effect on die shift ofthe sp carbon in the molecule. Calculation of approximate shifts can be made from the following parameters where (a, P, and y represent substituents on the same end of the double bond as the alkene carbon of interest, and (a , P , and y represent substituents on the far side. a +10.6... 

Related photochemical reactions in which carbon dioxide is eliminated are summarized in Table 10. As well as y-aryl, y-enone substituents effectively promote the reaction. A remarkable example is provided by dihydro-l,2-(6j5,ll/ )-santonine (3). This crystalline solid slowly liquefied on exposure to normal laboratory lighting and then recrystallized. The product, norepimaalienone (4) has lost the elements of carbon dioxide and the stereochemistry of the methyl-bearing carbon is inverted. Simple derivatives of compound 3 underwent the same reaction. The cyclopropanes produced are themselves photosensitive and if more forcing conditions are employed, alkene rather than cyclopropyl products are isolated. ... 

---