Anti-Markovnikov orientation

Organoboranes react with a mixture of aqueous NH3 and NaOCl to produce primary amines. It is likely that the actual reagent is chloramine NH2CI. Chloramine itself,hydroxylamine-O-sulfonic acid in diglyme, and trimethyl-silyl azide " also give the reaction. Since the boranes can be prepared by the hydroboration of alkenes (15-16), this is an indirect method for the addition of NH3 to a double bond with anti-Markovnikov orientation. Secondary amines can be prepared by the treatment of alkyl- or aryldichloroboranes or dialkylchlorobor-anes with alkyl or aryl azides. 

Ammonia can be added to double bonds (even ordinary double bonds) in an indirect manner by the use of hydroboration (15-16) followed by treatment with NH2CI or NH2OSO2OH (12-29). This produces a primary amine with anti-Markovnikov orientation. An indirect way of adding a primary or secondary amine to a double bond consists of aminomercuration followed by reduction (see 15-3 for the analogous oxymercuration-demercuration procedure), for example. 

Compared to a bromonium ion, the C-S bonds are stronger and the TS for nucleophilic addition is reached later. This is especially true for the sulfurane structures. Steric interactions that influence access by the nucleophile are a more important factor in determining the direction of addition. For reactions involving phenylsulfenyl chloride or methylsulfenyl chloride, the intermediate is a fairly stable species and ease of approach by the nucleophile is the major factor in determining the direction of ring opening. In these cases, the product has the anti-Markovnikov orientation.62... 

Both electronic and steric factors accounts for the anti-Markovnikov orientation of the addition. 

Now, just the same sort of rationalization can be applied to the radical addition, in that the more favourable secondary radical is predominantly produced. This, in turn, leads to addition of HBr in what is the anti-Markovnikov orientation. The apparent difference is because the electrophile in the ionic mechanism is a proton, and bromide then quenches the resultant cation. In the radical reaction, the attacking species is a bromine atom, and a hydrogen atom is then used to quench the radical. This is effectively a reverse sequence for the addition process but, nevertheless, the stability of the intermediate carbocation or radical is the defining feature. The terminologies Markovnikov or anti-Markovnikov orientation may be confusing and difficult to remember consider the mechanism and it all makes sense. 

Anti-Markovnikov orientation with nonbulky alkyl groups, all H s of BH, add to form a trialkylborane)... 

Protrfwn 6.25 Account for the anti-Markovnikov orientation in Problem 6.24(/). ... 

Water can be added indirectly, with anti-Markovnikov orientation, by treatment of the alkene with a 1 1 mixture of PhCH2NEt3+ BH4 and Me3SiCl, followed by addition of an aqueous solution of K2C03.152 For another method of anti-Markovnikov hydration, see 5-12. With substrates of the type C=C—Z (Z is as defined on p. 741) the product is almost always HO—C—CH—Z and the mechanism is usually nucleophilic,153 though electrophilic... 

Hypochlorous acid and hypobromous acid react with acyclic alkenes to give Mar-kovnikov products. In striking contrast, exclusive anti-Markovnikov orientation was observed in the transformation of methylenecycloalkanes with HOBr, and mixtures of chlorohydrins were formed with HOC1 146... 

The hydroxy group must be located on one of the doubly bonded carbons of the original alkene, so first draw all of the alkenes that meet this criterion. Examine the alkenes to determine whether it is possible to selectively add the OH group to the desired carbon. Remember that we can add the OH with either Markovnikov orientation (acid-catalyzed hydration or oxymercuration-reduction) or anti-Markovnikov orientation (hydroboration-oxidation), but we will have difficulty selecting between two carbons that are similarly substituted. 

Radical Addition of HBr to Unsymmetrical Alkenes Now we must explain the anti-Markovnikov orientation found in the products of the peroxide-catalyzed reaction. With an unsymmetrical alkene like 2-methylbut-2-ene, adding the bromine radical to the secondary end of the double bond forms a tertiary radical. 

Such an anti-Markovnikov hydration was impossible until H. C. Brown, of Purdue University, discovered that diborane (B2H6) adds to alkenes with anti-Markovnikov orientation to form alkylboranes, which can be oxidized to give anti-Markovnikov alcohols. This discovery led to the development of a large field of borane chemistry, for which Brown received the Nobel Prize in Chemistry in 1979. 

The BH3 THF reagent is the form of borane commonly used in organic reactions. BH3 adds to the double bond of an alkene to give an alkylborane. Basic hydrogen peroxide oxidizes the alkylborane to an alcohol. In effect, hydroboration-oxidation converts alkenes to alcohols by adding water across the double bond, with anti-Markovnikov orientation. 

The boron atom is removed by oxidation, using aqueous sodium hydroxide and hydrogen peroxide (HOOH or H2C>2) to replace the boron atom with a hydroxyl (—OH) group. The oxidation does not affect the orientation of the product, because the anti-Markovnikov orientation was established in the first step, the addition of BH3. 

CH3—CH —CH2Br isobutyl bromide (anti-Markovnikov orientation)... 

Markovnikov or anti-Markovnikov orientation, depending on the reagents. 

Markovnikov orientation anti-Markovnikov orientation MCPBA... 

A reaction in which one direction of bond making or bond breaking occurs preferentially over all other directions. For example, the addition of HC1 is regioselective, predicted by Markovnikov s rule. Hydroboration-oxidation is regioselective because it consistently gives anti-Markovnikov orientation, (p. 332)... 

In Section 8-3B, we saw the effect of peroxides on the addition of HBr to alkenes. Peroxides catalyze a free-radical chain reaction that adds HBr across the double bond of an alkene in the anti-Markovnikov sense. A similar reaction occurs with alkynes, with HBr adding with anti-Markovnikov orientation. 

Propose a mechanism for the reaction of pent-l-yne with HBr in the presence of peroxides. Show why anti-Markovnikov orientation results. 

Hydroboration-Oxidation In Section 8-7 we saw that hydroboration-oxidation adds water across the double bonds of alkenes with anti-Markovnikov orientation. A similar reaction takes place with alkynes, except that a hindered dialkylborane must be used to prevent addition of two molecules of borane across the triple bond. Di(second-ary isoamyl)borane, called disiamylborane, adds to the triple bond only once to give a vinylborane. (Amyl is an older common name for pentyl.) In a terminal alkyne, the boron atom bonds to the terminal carbon atom. 

The best experimental conditions to introduce a phenylseleno and an azido group to the alkene double bond are those which employ diphenyl diselenide, sodium azide and iodobenzene diacetate in methylene chloride. Under these conditions, however, the addition reaction occurs through the radical mechanism illustrated in Scheme 12 [581. The addition therefore occurs with an anti Markovnikov orientation and it is not stereospecific. The reaction is initiated by the oxidation of the azido anion to the azido radical, which adds to the alkene to afford a carbon radical. This is trapped by the PhSeSePh to afford the final product and a PhSe radical, which dimerizes to give the diselenide. 

The next stage requires equilibration and isomerization of 69 to 68, giving a 9 1 ratio of desired to undesired product. A Ni catalyst is also used for this reaction. Finally, the third stage consists of two transformations, where 68 is first isomer-ized to 4-pentenenitrile (70) under kinetic control, fortunately without producing much of the thermodynamically more stable 2-pentenenitrile (71). Compound 70 then undergoes a second hydrocyanation with anti-Markovnikov orientation (equation 9.40). In this last Ni-catalyzed stage of the overall process, a Lewis acid, such as Ph3B, is added to ensure that linear rather than branched product (72) forms. 

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