Trans-tert-butylation reaction

Reversible nature of Friedel-Crafts alkylation of benzene derivatives has been applied to remove ortho-tert-huty group, which is an essential substituent to isolate an atropisomeric anilide derivative as a stable compound at an ambient temperature. Simpkins and coworkers reported that during the AICI3 catalyzed trans-tert-butylation reaction of the particular enamide compound (12) in benzene, enamide function undergoes Friedel-Crafts alkylation to give phenylated product (13) in good yield (Scheme 6.12) [14]. Thus, in this case, Friedel-Crafts alkylation and dealkylation occur at the same time. 

With regard to isomerizations of double bonds, sulfinyl enynes gave imex-pected results when submitted to PKR. These chiral substrates were thought to give high asymmetric inductions due to the proximity of the chiral sulfm atoms to the reaction centers. Surprisingly, both cis and trans tert-butyl vinyl sulfoxides (237-238) were transformed into the same PK diastereoisomer 239 with high ee and moderate yields (Scheme 67) [103,104]. 

Predictive equations for the rates of decomposition of four families of free radical initiators are established in this research. The four initiator families, each treated separately, are irons-symmetric bisalkyl diazenes (reaction 1), trans-phenyl, alkyl diazenes (reaction 2), tert-butyl peresters (reaction 3) and hydrocarbons (reaction 4). The probable rate determining steps of these reactions are given below. For the decomposition of peresters, R is chosen so that the concerted mechanism of decomposition operates for all the members of the family (see below)... 

When colorless crystals of rac-s-trans-3,8-di-tert-butyl-l,5,6,10-tetraphenyl-deca-3,4,6,7-tetraene-l,9-diyne (123) were heated at 140 °C for 2 h, the ben-zodicylobutadiene derivative (126) was produced as green crystals. As shown in the sequence (Scheme 20), 123 is first isomerized to its s-ds-isomer (124), and intramolecular thermal reaction of the two allene moieties through a [2+2] conrotatory cyclization gives the intermediate 125, which upon further thermal reaction between acetylene moieties gives the final product 126 [19,22].This is another example of the crystal-to-crystal reaction. 

The reaction of 1 with hydrobromic acid gave quantitatively the cis adduct 14 (Scheme 11). The reaction of 1 with hydrochloric acid gave the cis adduct 15 in 79% yield and the trans adduct 16 in 18% yield. In these reactions, no other Si-Si bond cleavage products were obtained. The ladder polysilane 1 did not react with hydrofluoric acid. The reactions of 1,4-di-ter -butyl-2,2,3,3,5,5,6,6-octaisopropylbicyclo[2.2.0]hexasilane with hydrobromic acid and hydrochloric acid were attempted, but no reactions took place. This result is ascribed to steric hindrance by the tert-butyl groups on the bridgehead silicon atoms. 

Baker s yeast catalyzed the regioselective cycloaddition of stable aromatic nitrile oxides ArCNO [Ar = 2,6-C12C6H3, 2,4,6-Me3C6H2, 2,4,6-(MeO)3C6H2] to ethyl cinnamate, ethyl 3-(p-tolyl)acrylate, and tert-butyl cinnamates (218). Reactions of dichloro- and trimethoxybenzonitrile oxides with all three esters proceeded regio- and stereoselectively to form exclusively alkyl tran.v -3,5-diary 1 -... 

Lund and coworkers [131] pioneered the use of aromatic anion radicals as mediators in a study of the catalytic reduction of bromobenzene by the electrogenerated anion radical of chrysene. Other early investigations involved the catalytic reduction of 1-bromo- and 1-chlorobutane by the anion radicals of trans-stilhene and anthracene [132], of 1-chlorohexane and 6-chloro-l-hexene by the naphthalene anion radical [133], and of 1-chlorooctane by the phenanthrene anion radical [134]. Simonet and coworkers [135] pointed out that a catalytically formed alkyl radical can react with an aromatic anion radical to form an alkylated aromatic hydrocarbon. Additional, comparatively recent work has centered on electron transfer between aromatic anion radicals and l,2-dichloro-l,2-diphenylethane [136], on reductive coupling of tert-butyl bromide with azobenzene, quinoxaline, and anthracene [137], and on the reactions of aromatic anion radicals with substituted benzyl chlorides [138], with... 

Disubstituted dihydrofurans and dihydropyrans were prepared via allylic etherification [68] in a similar manner to dihydropyrroles (cf Section 9.4.6). Thus, diaste-reoisomeric ethers were generated by the reaction of cinnamyl tert-butyl carbonate with the copper alkoxide prepared from (Rj-l-octen-3-ol, depending on which enantiomer of the phosphoramidite ligand was used (Scheme 9.39). Good yields and excellent selectivities were obtained. RCM in a standard manner gave cis- and trans-dihydrofuran derivatives in good yield, and the same method was used for the preparation of dihydropyrans. 

The method of Kim et al.[89-93] starts from the synthesis of the three-carbon phosphonium salt according to the modified method of Corey et alJ94,95] The Wittig reaction of the phosphonium salt with a Z-protected a-amino aldehyde using potassium hexamethyldisilazanide provides the ds-alkene without racemization. Efficient hydrolysis of the orthoester without double bond migration is achieved by acidolytic hydrolysis with aqueous hydrochloric acid in tert-butyl alcohol under reflux conditions. Then, an a-amino acid methyl ester is coupled. The desired epoxide product is obtained by treatment with 3-chloroperoxybenzoic acid. The epoxidation reaction is stereoselective and predominantly provides one isomer (R,S S,R = 4-10 1). The trans-epoxide can also be prepared using a trans-alkene-containing peptide. A representative synthetic procedure to obtain the ds-epoxide isostere is detailed below. 

Styrene and substituted styrenes react with tetramesityldisilene 1, tetra-tert-butyl-disilene 21, and tetrakis(tert-butyldimethylsilyl)disilene 22 to afford the corresponding disilacyclobutane derivatives.127,134 Similarly, [2 + 2] additions occur between the disilenes with a C = C double bond in an aromatic ring135 and acrylonitrile.136 Bains et al. have found that the reaction of disilene 1 with trans-styrene- provides a 7 3 diastereomeric mixture of [2 + 2] adducts, 201 and 202 [Eq. (95)] the ratio is changed, when czs-styrene-Ji is used.137 The formation of the two diastereomeric cyclic adducts is taken as the evidence for a stepwise mechanism via a diradical or dipolar intermediate for the addition, similar to the [2 + 2] cycloaddition of phenylacetylene to disilene ( )-3, which gives a 1 1 mixture of stereoiso-meric products.116,137... 

The radical cations of fulvene systems are of interest, because steric and electronic factors might favor a perpendicular structure and because the energy difference between the respective cis and trans isomers are expected to be small. However, the chloranil photosensitized reaction resulted in CIDNP effects, indicating planar or slightly twisted structures. The Z- and E-2-tert-butyl-6-(dimethylamino)fulvene [20, R = — N(CH3)2] radical cations rearrange readily whereas di-/er/-butylfulvene [20, R = — C(CH3)3] showed no interconversion under comparable experimental conditions [160]. 

Heck and Suzuki type couplings have been described by Fu [2] et al. The reaction of chlorobenzene and styrene in refluxing dioxane in the presence of [Pd2(dba)3 ] and the electron rich tri-tert.-butyl-phosphane [eq. (a)] gives rise to trans-stilbene in 83% yield. Besides the choice of the ligand - aryl phosphanes, tri-n-butyl-phosphane or tri-cyclo-hexyl-phosphane show no conversion - the base is also crucial for success. Cesium carbonate gives the best results, although the cheaper potassium phosphate gives comparable yields. 

There are few examples of isomerization of achiral unfunctionalized olefins into enantiomerically enriched olefins. The most successful is the transformation of meso,trans-4-tert-butyl-l-vinylcyclohexane (1) into the corresponding alkene (S)-2 (Scheme 1) [6]. When a C2-symmetric titanocene catalyst, which can easily be prepared in three steps from enantiopure starting material, is used in the presence of LiAlH4 as activator the product is obtained in 80% ee. The rate of the reaction and the optical purity of the product are highly dependent on reaction temperature. The lower enantiomeric purity obtained at higher temperatures is apparently because of racemization by equilibration of the product, a process which is promoted by longer reaction times. 

When compounds V (R = ethyl, isopropyl, cyclopentyl, n-butyl, or tert-butyl) have been heated 30-50°C above their melting points, VIII and the corresponding olefins have been obtained by (3 elimination (87,94). The course of the reaction has been controlled by the use of the deuterium-labeled compound V (R = CD2Me). It has been shown that all of the deuterium occurred in the ethylene formed by thermolysis (94). When R is methyl or phenyl, the thermolysis of V results in formation of IX. The styryl derivatives of V (R = cis-CH=CHPh and trans-CH=CHPh) have also been synthesized from VI and the corresponding Grignard reagents (94). Interestingly, thermolysis of these deriva-... 

The P-addition of alkyl radicals to 4-methyl-2-(arylsulfinyl)-2-cyclopentenone 117 has been shown to occur in a completely stereocontrolled manner. Of a mixture of (4/ )- and (45)-117, only (4R)-117 reacts with t-Bu and i-Pr radicals to give the trans adducts 119a and 119b in 99% yield, while (45)-117 remained entirely unreacted. The stereochemical outcome of the reaction shows that the alkyl radical approaches from the side opposite to the aryl moiety in an antiperiplanar orientation to the carbonyl and sulfoxide bond. The 2,4,6-triisopropylphenyl group on sulfur plays a critical role, as it effectively shields the olefin face at the P-position by one of the isopropyl groups. This was confirmed by the 1 1 diastereomeric mixture obtained in the reaction of 4-methyl-2-(p-tolylsulfmyl)-2-cyclopentanone with the tert-butyl radical. 

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