1.3- Cyclohexadiene addition-protonation reactions

The reaction of tetrachlorothiophene 1,1-dioxide 53 with a dienophile 64 affords the primary product 65 in a stereospecific manner because of steric demand [162, 163]. In 65, the cyclohexadiene ring protons are placed in close proximity to the other ring double bond. This enables the hydrogen atom transfer to take place stereospecifically to give 66 (Scheme 37). In the case of the dienophile 67, such a reaction is impossible, and the normal product 68 was obtained (Scheme 38). An additional two examples are also shown below (Scheme 39) [162-165]. 

Reduction of benzenoid hydrocarbons with solvated electrons generated by the solution of an alkali metal in liquid ammonia, the Birch reaction [34], involves homogeneous electron addition to the lowest unoccupied 7t-molecular orbital. Protonation of the radical-anion leads to a radical intermediate, which accepts a further electron. Protonation of the delocalised carbanion then occurs at the point of highest charge density and a non-conjugated cyclohexadiene 6 is formed by reduction of the benzene ring. An alcohol is usually added to the reaction mixture and acts as a proton source. The non-conjugated cyclohexadiene is stable in the presence of... 

In this cyclodecarbonylation reaction, a ketene species is unlikely to be the reaction intermediate as added alcohols produce no esters. As shown in Scheme 6.26, the ruthenium acyl species 72 is likely to be the intermediate [25], which is prone to decarbonylationto give ruthena-cyclohexadiene 73 this species undergoes subsequent reductive elimination to form 2H-indene. Addition of proton or Ru to species 74 generated the benzylic cation 75, which after a 1,2-aryl shift gave the observed products. 

These addition reactions require formation of an imino-cyclohexadiene intermediate (Fig. 13.41). In cases where the ipso substituent is a proton, tautomeriza-tion to form the substituted aniline derivative is fast, and such intermediates have not been isolated. On the other hand, in situations where the nucleophile adds to a substituted ring position, the intermediate can undergo further secondary reactions. For example Novak et al. showed that the 4-biphenylylnitrenium ion reacts with water forming the imine cyclohexadiene intermediate 74, which in turn experiences an acid-catalyzed phenyl shift reaction to 76 via 75 (Fig. 13.42). 

Reactions of the HNiL3CN complex with 1,3-cyclopentadiene, 1,3-cyclo-hexadiene, and 1,3-cyclooctadiene gave intermediates with decreasing stabilities in that order the 1,3-cyclooctadiene intermediate was not spectroscopically observable. The cyclohexadiene adduct was shown to be the cyclohexadienyl complex 12 by its proton spectra, with resonances of H , Hb, and —(CH2)3— at 14.53, 6.06, and 8.47, respectively these values are close to the chemical shifts found earlier (51) for 13 14.52,5.86, and 8.48. The reaction of DNi[P(OMe)3]X with cyclopentadiene gives 13-d, with addition of D and Ni to the same side of the ring (52). Backvall and Andell (55) have shown, using Ni[P(OPh)3]4 and deuterium cyanide (DCN), that addition of D and CN to cyclohexadiene is stereospecifically cis, as expected for jt-allyl intermediate 12. 

However, not only the protonating ability of IIGeCh or systems derived from it determine the addition to aromatic carbon-carbon bonds, in contrast to the behavior of other HX acids. The specific features of HGeCl3 are probably manifested at the step of the cyclohexadiene derivative formation. Energy is obviously lost during the conversion from a-complex to cyclohexadiene. The formation of the cyclohexadiene-GeCl2 molecular complex (the GeCl2 present in the reaction mixture is a result of a well-known reaction, cf. Section III) is likely to be responsible for the equilibrium shift in the direction of the cyclohexadiene. It is likely that application of some other compounds which provide such shift by complexation with cyclohexadiene will enhance the addition of other HX acids to aromatic double bonds. 

The chiral anisole derivative 37 has been used in the synthesis of several asymmetric functionalized cyclohexenes (Table 9) [22]. In a reaction sequence similar to that employed with racemic anisole complexes, 37 adds an electrophile and a nucleophile across C4 and C3, respectively, to form the cyclohexadiene complex 38. The vinyl ether group of 38 can then be reduced by the tandem addition of a proton and hydride to C2 and Cl, respectively, affording the alkene complex 39. Direct oxidation of 39 liberates cydohexenes 40 and 41, in which the initial asymmetric auxiliary is still intact. Alternatively, the auxiliary may be cleaved under acidic conditions to afford /y3 -allyl complexes, which can be regioselectively attacked by another nucleophile at Cl. Oxidative decomplexation liberates the cyclohexenes 42-44. HPLC analysis revealed high ee values for the organic products isolated both with and without the initial asymmetric group. 

Tj -Cyclohexadienyl ruthenium complexes have been obtained either by addition of nucleophiles to the arene ring of arene ruthenium(II) complexes or by protonation of ruthenium(O) complexes. The first complex prepared, the benzene cyclohexadienyl ruthenium cation 236a, has been obtained together with the zero-valent arene cyclohexadiene ruthenium(O) complex 196a, by reaction of 235a with lithium aluminum hydride (118) [Eq. (27)]. 

It was determined that carbon nucleophiles derived from carbon acids with p/fa > 22 or so are sufficiently reactive to combine with the diene ligand rapidly at —78°C to produce an anionic intermediate (Scheme 25). With a few exceptions, the regioselectivity favors formation of the homoallyl anionic complex from addition at C-2, by kinetic control. This intermediate can be quenched with protons to give the terminal alkene, or can react with excess CO to produce an acyl iron intermediate. Following the recipes of Collman s reaction, the acyl iron intermediate can lead to methyl ketones, aldehydes, or carboxylic acids. The processes are illustrated with the 1,3-cyclohexadiene complex (Scheme 25). ... 

Reaction of the anionic cyclohexadienyl CrfCOlj, obtained by addition of a nitrile stabilized carbanion to [CrfbenzeneffCOlj], with Mel, regenerates the starting complex. However, treatment of the same intermediate with a strong acid at low temperature affords a mixture of isomeric cyclohexadienes. With time, the reaction tends to converge to the most stable diene (Scheme 2) [ 15-18]. It has also been reported that protonation under a CO atmosphere allows recycling of Cr(CO)g [19]. 

Tributyltin hydride has been replaced by the silylated cyclohexadienes as the proton source7 In addition, zinc and indium have been applied to initiate similar ring-expansion reactions 7 ... 

Being anionic carbonyl synthons, the nitroalkanes have been explored extensively for their conversion into the corresponding carbonyl compounds. For example, the embedment of a nitroalkane onto an activated basic silica gel or the blockage of the C-protonation of nitronate with a protonated concave pyridine. The reaction under the latter condition is called the soft Nef reaction. In addition, the introduction of a y-trimethylsilyl group is proved to smooth the Nef reaction. Moreover, when a primary nitroalkane is treated with nitrite/acetic acid, a carboxylic acid is resolved. Furthermore, the oxidative Nef reaction has successfully converted the nitro cyclohexadienes into the substituted phenols via a nucleophilic addition. 

The paUadium-catalyzed reactions occurred with the simple combination of [Pd(allyl) Cl]j and added phosphine, or with Pd(PPh3) and an acid co-catalyst. The scope of these reactions encompassed the additions of arylamines. As shown in Equation 16.81, reaction of various arylamines with cyclohexadiene occurred with high enantioselectivity using Trost s ligand. This ligand is discussed in more detail in Chapter 20. These reactions, and nickel-catalyzed reactions, occur by nucleophilic attack of amines on ir-allyl intermediates generated by protonation of diene complexes or insertion of dienes into palladium hydrides. 

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