Allyl alcohol, alkylation with

Another interesting example of dehydrative C-C coupling involves the alkylation of benzimidazole 36 with allyl alcohol 37, which is catalysed by complex 39 [15], The reaction is believed to proceed by alkene complex formation with the allyl alcohol 37 with loss of water from the NH proton of the NHC ligand and OH of the allyl alcohol to give an intermediate Ji-allyl complex. The initially formed 2-allylbenzimidazole isomerises to a mixture of the internal alkenes 38 (Scheme 11.9). 

The first examples of iridium-catalyzed allylic substitution [1] occurred between stabilized carbon nucleophiles and both alkyl- and aryl-substituted allylic alcohol derivatives with exceptional selectivity for the branched substitution product. 

The first reactions concerned (Simons and Archer, 27) alkylation of benzene with propylene to form isopropylbenzene, with isobutene to form f-butylbenzene and di-f-butylbenzene, and trimethylethylene to form amylbenzene. Later on (Simons and Archer, 28) studied these and other reactions in more detail and showed that high yields could be obtained and that the product was not contaminated with tars or other obnoxious impurities. It was shown that the products obtained with trimethylethylene were mono- and di-f-amylbenzene, that phenyl-pentane resulted from the use of pentene-2, and that cyclohexene produced cyclohexylbenzene. Cinnamic acid reacted with benzene (Simons and Archer, 29) to form /3-phenylpropionic acid and allyl benzene reacted with benzene to form 1,2-diphenylpropane. It is interesting to note that although allyl alcohol reacted with benzene to form 1,2-diphenylpropane, the intermediate in the reaction, allylbenzene, was isolated and identified. This shows that in this case the hydroxyl reacted at a more rapid rate than the double bond. Both di- and triisobutylene reacted with phenol (Simons and Archer, 30) at 0°, when using hydrogen fluoride containing only relatively small quantities of water, to form f-butyl-benzene, but diisobutylene with 70% hydrogen fluoride produced p-f-octylphenol. Cyclohexene reacted with toluene to form cyclohexyl-toluene and octene-1 rapidly reacted with toluene to form 2-octyltoluene (Simons and Basler, 31). 

Murahashi alkylation. Murahashi alkylation (8, 346-347) of the optically active allylic alcohol 2 with butyllithium results in almost exclusive (99%) y-al-kylation to give a mixture of (S)-(E)-3 and (R)-(Z)-3 with only slight loss of chirality and with predominant syn-stereochemistry.1 This syn-stereochemistry is opposite... 

Another approach in the study of the mechanism and synthetic applications of bromination of alkenes and alkynes involves the use of crystalline bromine-amine complexes such as pyridine hydrobromide perbromide (PyHBts), pyridine dibromide (PyBn), and tetrabutylammonium tribromide (BiMNBn) which show stereochemical differences and improved selectivities for addition to alkenes and alkynes compared to Bn itself.81 The improved selectivity of bromination by PyHBn forms the basis for a synthetically useful procedure for selective monoprotection of the higher alkylated double bond in dienes by bromination (Scheme 42).80 The less-alkylated double bonds in dienes can be selectively monoprotected by tetrabromination followed by monodeprotection at the higher alkylated double bond by controlled-potential electrolysis (the reduction potential of vicinal dibromides is shifted to more anodic values with increasing alkylation Scheme 42).80 The question of which diastereotopic face in chiral allylic alcohols reacts with bromine has been probed by Midland and Halterman as part of a stereoselective synthesis of bromo epoxides (Scheme 43).82... 

Titanium acetylides react with 3-benzyl-tetrahydro-l,3-oxazines and 1,3-oxazolidines to give the corresponding / -aminoacetylenes in modest to good yield.296 Vinyl Ti(iv) species prepared by the alkylation of vinylcarbene complexes with BTCl react with aldehydes to give allylic alcohols. Reaction with terminal alkynes produces conjugated dienes, in which a vinyl group regioselectively bonds to the unsubstituted side of carbon-carbon triple bond.297... 

Alkylation of the allylic alcohol 100 with the silyl alkyl triflate gives an ether 101 from which the Me3Si group can be removed with BuLi. The new substituent (CH2OH) in 103 must be axial as it has to overlap with the p-orbitals of the alkene as it moves.17... 

The reaction of nitrile oxides prepared in situ by dehydration of aliphatic nitro compounds with triethylamine and phenyl isocyanate with allylic alcohols proceeds with low stereocontrol to give a predominance of the /-product. Allyl ethers as the dipolarophiles can lead to high excesses of the y-cycloadducts, with the stereoselection increasing with increasing bulkiness of the alkyl residue at the stereocenter. 

The crucial steps in the synthesis route developed by them are the alkylation of the monoprotected tris-allylic alcohol 8 with iodomethyltributyltin, to yield 9,... 

The allylic alcohol products from Morita-Baylis-Hillman reactions were shown to participate in a DMAP-mediated Tsuji-Trost-type reaction with /3-diketones or /3-ketoesters, forming the C-allylation product without requiring the use of palladium. Previously, it was shown that allylic alcohols combined with /8-ketoesters and DMAP afforded the transesterification products, in which the allylic alcohol displaced the ester substituent. The difference between these diverging reaction pathways is likely due to the electron-withdrawing group on the allylic alcohol in the MBH adducts vs. just alkyl substituents in the latter case. 

Several years ago, we reported the synthesis and synthetic utility of lithium aminoborohydrides (LABs) a new class of powerful, safe, and highly selective reducing agents (2, 3). These reagents performed many of the transformations for which lithium aluminum hydride is usually used. Thus, the following reduction reactions were carried out with LABs aldehydes and ketones to alcohols, esters to alcohols, oc,P>unsaturated ketones to allylic alcohols, a,P-unsaturated esters to allylic alcohols, alkyl halides to hydro-carbons, azides to amines, and epoxides to alcohols. These reduction reactions are summarized in Figure 3. 

Allylation with allyl borates takes place smoothly under neutral conditions. Allylic alcohols are also used for allylation in the presence of boron oxide by in situ formation of allylic borates[125]. Similarly, arsenic oxide is used for allylation with allylic aleohols[126]. In addition, it was claimed that the allyl alkyl ethers 201. which are inert by themselves, can be used for the allylation in the presence of boron oxide[127]. 

Alkylation with a vatiety of common alkyl halides oi sulfates gives stable dialkylcyanamides. However, the intermediate monoalkylated compounds usually cannot be isolated and cychc trimers or cotrimers with cyanamide ate obtained (13). The reaction can be carried out efficientiy in water or alcohol. Allyl chloride is an especially useful reagent, producing diallylcyanamide [538-08-9J (4). 

Benzyl and allyl alcohols which can generate stabilized caibocations give Friedel-Crafts alkylation products with mild Lewis acid catalysts such as scandium triflate. ... 

In the first of these sequences, often called the Torgov-Smith synthesis, the initial step consists in condensation of a 2-alkyl-cyclopentane-l,3-dione with the allyl alcohol obtained from 6-methoxy-l-tetralone and vinylmagnesium chloride. Although this reaction at first sight resembles a classic SN displacement, the reaction is actually carried out with only a trace of base. 

The AE reaction catalyzed by titanium tartrate 1 and with alkyl hydroperoxide as terminal oxidant has been applied to a large variety of primary allylic alcohols containing all eight basic substitution patterns. A few examples are presented in Table 6.2. 

The phenomenon that early transition metals in combination with alkyl hydroperoxides could participate in olefin epoxidation was discovered in the early 1970s [30, 31]. While m-CPBA was known to oxidize more reactive isolated olefins, it was discovered that allylic alcohols were oxidized to the corresponding epoxides at the same rate or even faster than a simple double bond when Vv or MoVI catalysts were employed in the reaction [Eq. (2)] [30]. 

Organocopper-boron trifluoride (RCu BF3) reacts with allylic alcohols, such as 3-phenyl-2-propenol, 2-butenol, 3-buten-2-ol, 2,4-hexadienol, 3-methyl-2-butenol, to give the y-alkylation... 

Direct alkylation of allylic alcohols via the (allyloxy)phosphonium ion intermediate normally proceeds with anti-y selectivity for the Cyclic system, and sy/i-y selectivity for the acyclic system (see Table l)35 36. 

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