Alkenes anti-Markovnikov addition

The addition of hydrogen halides to simple alkenes, in the absence of peroxides, takes place by an electrophilic mechanism, and the orientation is in accord with Markovnikov s rule. " When peroxides are added, the addition of HBr occurs by a free-radical mechanism and the orientation is anti-Markovnikov (p. 985). It must be emphasized that this is true only for HBr. Free-radical addition of HF and HI has never been observed, even in the presence of peroxides, and of HCl only rarely. In the rare cases where free-radieal addition of HCl was noted, the orientation was still Markovnikov, presumably beeause the more stable product was formed. Free-radical addition of HF, HI, and HCl is energetically unfavorable (see the discussions on pp. 900, 910). It has often been found that anti-Markovnikov addition of HBr takes place even when peroxides have not been added. This happens because the substrate alkenes absorb oxygen from the air, forming small amounts of peroxides... 

EXERCISE 11.1 Draw the product that you would expect from an anti-Markovnikov addition of H and Br across the following alkene ... 

Answer In order to determine whether or not to use peroxides, we must decide whether the desired transformation represents a Markovnikov addition or an anti-Markovnikov addition. When we compare the starting alkene above with the desired product, we see that we need to place the Br at the more substituted carbon (i.e., Markovnikov addition). Therefore, we need an ionic pathway to predominate, and we should not use peroxides. We just use HBr ... 

A quick glance at the products indicates that we are adding H and OH across the alkene. Let s take a closer look and carefully analyze the regiochemistry and stereochemistry of this reaction. The OH is ending up on the less substituted carbon, and therefore, the regiochemistry represents an anti-Markovnikov addition. But what about the stereochemistry Are we seeing a syn addition here, or is this anti addition ... 

Answer (a) These reagents will accomplish an anti-Markovnikov addition of OH and H. The stereochemical outcome will be a syn addition. But we must first decide whether stereochemistry will even be a relevant factor in how we draw our products. To do that, remember that we must ask if we are creating two new stereocenters in this reaction. In this example, we are creating two new stereocenters. So, stereochemistry is relevant. With two stereocenters, there theoretically could be four possible products, but we will only get two of them we will only get the pair of enantiomers that come from a syn addition, hi order to get it right, let s redraw the alkene (as we have done many times earlier), and add OH and H like this ... 

Although zirconium bisamides Cp2Zr(NHAr)2 do not catalyze the hydroamination of alkenes (see above), they are catalyst precursors for the hydroamination of the more reactive double bond of allenes to give the anti-Markovnikov addition product (Eq. 4.96) [126]. 

The addition of hydrogen halide to alkene is another classical electrophilic addition of alkene. Although normally such reactions are carried out under anhydrous conditions, occasionally aqueous conditions have been used.25 However, some difference in regioselectivity (Markovnikov and anti-Markovnikov addition) was observed. The addition product formed in an organic solvent with dry HBr gives exclusively the 1-Br derivative whereas with aq. HBr, 2-Br derivative is formed. The difference in the products formed by the two methods is believed to be due primarily to the difference in the solvents and not to the presence of any peroxide in the olefin.26... 

Redical Addition to Alkenes the Anti-Markovnikov Addition of Hydrogen Bromide... 

A Summary of Markovnikov versus Anti-Markovnikov Addition of HBr to Alkenes... 

Similar to the addition of secondary phosphine-borane complexes to alkynes described in Scheme 6.137, the same hydrophosphination agents can also be added to alkenes under broadly similar reaction conditions, leading to alkylarylphosphines (Scheme 6.138) [274], Again, the expected anti-Markovnikov addition products were obtained exclusively. In some cases, the additions also proceeded at room temperature, but required much longer reaction times (2 days). Treatment of the phosphine-borane complexes with a chiral alkene such as (-)-/ -pinene led to chiral cyclohexene derivatives through a radical-initiated ring-opening mechanism. In related work, Ackerman and coworkers described microwave-assisted Lewis acid-mediated inter-molecular hydroamination reactions of norbornene [275]. 

Rhodium(I) and ruthenium(II) complexes containing NHCs have been applied in hydrosilylation reactions with alkenes, alkynes, and ketones. Rhodium(I) complexes with imidazolidin-2-ylidene ligands such as [RhCl( j -cod)(NHC)], [RhCl(PPh3)2(NHC)], and [RhCl(CO)(PPh3)(NHC)] have been reported to lead to highly selective anti-Markovnikov addition of silanes to terminal olefins [Eq. 

This radical anti-Markovnikov addition of HX to alkenes is restricted to HBr both HI and HCl add in a Markovnikov fashion by an ionic... 

According to the reasoning we have so far used, protonation of the double bond in this alkene should give the secondary carbocation rather than the alternative primary carbocation. Based on the information given in the question, it does not. We must get the primary carbocation, which is then quenched by bromide, i.e. anti-Markovnikov addition. It is not necessary to remember what Markovnikov or anti-Markovnikov additions mean, we just need to consider the carbocation intermediates and their relative stability. 

The hydrative cyclization involves the formation of a ruthenium vinylidene, an anti-Markovnikov addition of vater, and cyclization ofan acylmetal species onto the alkene. Although the cyclization may occur through a hydroacylation [32] (path A) or Michael addition [33] (path B), the requirement for an electron- vithdra ving substituent on the alkene and lack of aldehyde formation indicate the latter path vay to be the more likely mechanism. Notably, acylruthenium complex under vent no decarbonylation in this instance. 

Hydroboration-oxidation of alkenes preparation of alcohols Addition of water to alkenes by hydroboration-oxidation gives alcohols via anti-Markovnikov addition. This addition is opposite to the acid-catalysed addition of water. Hydrohoration is regioselective and syn stereospecific. In the addition reaction, borane bonds to the less substituted carbon, and hydrogen to the more substituted carbon of the double bond. For example, propene reacts with borane and THF complex, followed by oxidation with basic hydrogen peroxide (H2O2), to yield propanol. 

Exceptions to the Markovnikov rule when hydrogen bromide reacts with unsym-metric alkenes have long been known.117,118 The reaction for this anti-Markovnikov addition was explained as being a chain reaction with the involvement of bromine atoms influenced by the presence of peroxides.119-121 Both added peroxides and peroxides formed by the action of oxygen (air) on the alkene are effective. 

The use of silica-supported Zn(BH4)2 is a useful procedure for the hydration of unactivated alkenes and alkynes.559 The main products are usually formed as a result of anti-Markovnikov addition. In contrast to acid-catalyzed hydration (see Section 6.1.2), this procedure allows the transformation of alkynes to alcohols. 

Of the isomeric aldehydes indicated in Eq. (7.1), the linear aldehyde corresponding to anti-Markovnikov addition is always the main product. The isomeric branched aldehyde may arise from an alternative alkene insertion step to produce the [RCH(Me)Co(CO)3] or [RCH(Me)Rh(CO)(PPh3)2] complexes, which are isomeric to 2 and 8, respectively. Alternatively, hydroformylation of isomerized internal alkenes also give branched aldehydes. The ratio of the linear and branched aldehydes, called linearity, may be affected by reaction conditions, and it strongly depends on the catalyst used. Unmodified cobalt and rhodium carbonyls yield about 3-5 1 mixtures of the normal and iso products. 

This process has been coupled with meta addition of a carbonyl anion equivalent and the controlled exo addition of the incoming nucleophile to generate acorenone and acorenone B stereospecifically from [(o-methylanisole)Cr(CO)3] (63 Scheme 14).123 The first step is addition of a cyanohydrin acetal anion (64) to the less-hindered meta position in [(o-methylanisole)Cr(CO)3]. Addition of allylMgBr to the resulting ketone, anti-Markovnikov addition of HBr to the alkene, substitution for Br by CN, and coordina-... 

Cyanosulfenylation is generally conducted by mixing the alkene with 1 in CH3CN followed by addition of finely powdered NaCN at 25°. Addition of dimethyl sulfide sometimes improves the yield. The adducts are all assumed to be trans, but regioselectivity is a more critical question. With monosubstituted alkenes, only anti-Markovnikov addition is observed. Markovnikov adducts are favored by use of the less nucleophilic (CH3)3SiCN. 

C is correct. Anti-Markovnikov alkene free radical addition is demonstrated by reaction mechanisms 1 and 2, both of which rely on peroxides as reagents. Based on tine experimental results provided by the question stem, anti-Markovnikov addition only succeeds using HBr. 

A well-known example of the application of mechanistic understanding to help to control product yields is also of commercial significance - the addition of HBr to alkenes which may occur via cationic or radical mechanisms, Scheme 2.1 [2a]. Very pure alk-l-enes (1), in the absence of peroxides, react to give the 2-bromo-products (2) by Markovnikov addition. In the presence of peroxides or other radical sources, anti-Markovnikov addition gives the 1-bromo-products (3). 

Addition reactions to unsymmetrical alkenes in which a reagent with the structure H—X transfers the H atom to the less-substituted C atom and the X group to the more substituted C atom give, according to an old nomenclature, a so-called Markovnikov addition product. On the other hand, addition reactions of reagents H—X in which the H atom is transferred to the more substituted C atom of an unsymmetrically substituted C=C double bond and the X group is transferred to the less substituted C atom lead to a so-called anti-Markovnikov addition product. 

The hydroboration of unsymmetrical alkenes thus gives monoalkylboranes (addition of H—BH2), dialkylboranes (addition of H—BHR), or trialkylboranes (addition of H—BR2), which are typical anti-Markovnikov products. Therefore, the reaction sequence hydrobora-tion/oxidation/hydrolysis brings about the anti-Markovnikov addition of H20 to unsymmetrically substituted alkenes. 

Neither product has its alcohol functional group on the carbon atom that is functionalized in the target compound. Alcohol C needs its functional group moved two carbon atoms, but alcohol D needs it moved only one carbon atom. Converting alcohol D to an alkene functionalizes the correct carbon atom Anti-Markovnikov addition of HBr converts the alkene to an alkyl halide with the bromine atom on the correct carbon atom. 

Note that although the conversion of 7.11 to 7.12 assumes anti-Markovnikov addition, the Markovnikov product also gives butane. Conversion of 7.9 to 7.11 could also take place by prior coordination of alkene followed by the oxidative addition of dihydrogen. Indeed this parallel pathway for the formation of 7.11 does operate. Like the equilibrium shown between RhClL3, 7.9, and the dimer [RhClL L, there is an equilibrium between 7.9 and the alkene coordinated complex RhCl(alkene)L2. 

C. Bruneau, and P. H. Dixneuf, Metal Yinylidenes and Allenylidenes in Catalysis Applications in Anti-Markovnikov Additions to Terminal Alkynes and Alkene Metathesis, Angew. Chem. Int. Ed. 45, 2176-2203 (2006). 

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