Butadiene oxidative cyclization

The oxidative coupling of two molecules of butadiene with Pd(0) forms the bis-TT-allylpalladium complex 31, which is the resonance form of 2,5-divinyb palladacyclopentane (30) formed by oxidative cyclization. 

Oxidative cyclization of butadiene and trapping with a nucleophlla... 

Pd-cataly2ed reactions of butadiene are different from those catalyzed by other transition metal complexes. Unlike Ni(0) catalysts, neither the well known cyclodimerization nor cyclotrimerization to form COD or CDT[1,2] takes place with Pd(0) catalysts. Pd(0) complexes catalyze two important reactions of conjugated dienes[3,4]. The first type is linear dimerization. The most characteristic and useful reaction of butadiene catalyzed by Pd(0) is dimerization with incorporation of nucleophiles. The bis-rr-allylpalladium complex 3 is believed to be an intermediate of 1,3,7-octatriene (7j and telomers 5 and 6[5,6]. The complex 3 is the resonance form of 2,5-divinylpalladacyclopentane (1) and pallada-3,7-cyclononadiene (2) formed by the oxidative cyclization of butadiene. The second reaction characteristic of Pd is the co-cyclization of butadiene with C = 0 bonds of aldehydes[7-9] and CO jlO] and C = N bonds of Schiff bases[ll] and isocyanate[12] to form the six-membered heterocyclic compounds 9 with two vinyl groups. The cyclization is explained by the insertion of these unsaturated bonds into the complex 1 to generate 8 and its reductive elimination to give 9. 

Nickel(O) complexes are extremely effective for the dimerization and oligomerization of conjugated dienes [8,9]. Two molecules of 1,3-butadiene readily undergo oxidative cyclization with a Ni(0) metal to form bis-allylnickel species. Palladium(O) complexes also form bis-allylpalladium species of structural similarity (Scheme 2). The bis-allylpalladium complexes show amphiphilic reactivity and serve as an allyl cation equivalent in the presence of appropriate nucleophiles, and also serve as an allyl anion equivalent in the presence of appropriate electrophiles. Characteristically, the bis-allylnickel species is known to date only as a nucleophile toward carbonyl compounds (Eq. 1) [10,11],... 

The reaction of CO2 with 1,3-butadienes in the presence of Ni catalysts usually gave an isomeric mixture of carboxylic acids 89 and 90 after hydrolysis (Scheme 32).47,48 The oxa-7r-allylnickel complexes 87 and 88 might be the reaction intermediates, which could be formed through oxidative cyclization of Ni(0) with C02 and the dienes. When Me2Zn was used as a transmetallation agent to react with the oxa-7r-allylnickel intermediates under a C02 atmosphere, further carboxylation took place at the 7r-allylnickel unit. Thus, the 1,4-diesters 95 were obtained after acidic hydrolysis and treatment with diazomethane as shown in Scheme 32.47... 

Cyclization of butadiene catalysed by Ni(0) catalysts proceeds via 7r-allylnickel complexes. At first, the metallacyclic bis-7i-allylnickel complex 6, in which Ni is bivalent, is formed by oxidative cyclization. The bis-7r-allyl complex 6 may also be represented by cr-allyl structures 7, 8 and 9. Reductive elimination of 7, 8 and 9 produces the cyclic dimers 1, 2 and 3 by [2+2], [2+4] and [4+4] cycloadditions. Selectivity for 1, 2 and 3 is controlled by phosphine ligands. The catalyst made of a 1 1 ratio of Ni and a phosphine ligand affords the cyclic dimers 1, 2 and 3. In particular, 1 and 3 are obtained selectively by using the bulky phosphite 11. 1,2-Divinylcyclobutane (1) can be isolated only at a low temperature, because it undergoes facile Cope rearrangement to form 1,5-COD on warming. Use of tricyclohexylpho-sphine produces 4-vinylcyclohexene (2) with high selectivity. 

Generation of a-Acyl Radicals. As a one-electron oxidant, Ce can promote the formation of radicals from carbonyl compounds. In the presence of interceptors such as butadiene and alkenyl acetates, the a-acyl radicals undergo addition. The carbonyl compounds may be introduced as enol silyl ethers, and the oxidative coupling of two such ethers may be accomplished. Some differences in the efficiency for oxidative cyclization of, s-, and ,f-unsaturated enol silyl ethers using CAN and other oxidants have been noted (eq 14). ... 

In cyclization of conjugated dienes, typically butadiene, coordination of two molecules of butadiene gives rise to the bis-jr-allyl complexe 12. The distance between the terminals of two molecules of butadiene becomes closer by 7r-coordination to Pd(0), and the oxidative cyclization is thought to generate either the l-pallada-2,5-divinylcyclopentane 13 or l-pallada-3,7-cyclononadiene 14. 

N-Acylnitroso compounds 4 are generated in situ by periodate oxidation of hydroxamic acids 3 and react with 1,3-dienes (e.g. butadiene) to give 1,2-oxazines 5 (Scheme 6.3). The periodate oxidation of 4-O-protected homo-chiral hydroxamic acid 6 occurs in water in heterogeneous phase at 0°C, and the N-acylnitroso compound 7 that is generated immediately cyclizes to cis and tranx-l,2-oxazinolactams (Scheme 6.4) [17a, b]. When the cycloaddition is carried out in CHCI3 solution, the reaction is poorly diastereo-selective. In water, a considerable enhancement in favor of the trans adduct is observed. 

Further variations of the general scenario described in Scheme 4 consist in trapping adduct radical 48 before oxidation occurs7. This can be achieved if intramolecular radical additions are possible, as is the case in radical 62. Oxidation of 62 to the corresponding allyl cation is slower than 6-ew-cyclization to the chlorobenzene ring to form radical 63, which subsequently is oxidized to yield tetrahydronaphthalene 64 as the main product (equation 27). This sequence does not work well for other dienes such as 2,3-dimethyl-1,3-butadiene, for which oxidation of the intermediate allyl radical is too rapid to allow radical cyclization onto the aromatic TT-system. 

The first total synthesis of D/E-trans annellated yohimbines, e.g., ( )-yohim-bine (74) and ( )-pseudoyohimbine (88), was published in preliminary form by van Tamelen and co-workers (218) in 1958, while full details (219) appeared only in 1969. Key building block 393, prepared from butadiene and p-quinone, was condensed with tryptamine, yielding unsaturated amide 394, which was subsequently transformed to dialdehyde derivative 396. Cyclization of the latter resulted in pseudoyohimbane 397. Final substitution of ring E was achieved via pyrolysis, oxidation, and esterification steps. As a result of the reaction sequence, ( )-pseudoyohimbine was obtained, from which ( )-yohimbine could be prepared via C-3 epimerization. 

Examples of both oxidation and reduction have been found. Breil, Heimbach, Kroner, Muller and Wilke (130) have studied the cyclization of butadiene. Three different cyclic trimers of butadiene have been obtained depending on the catalyst system. These are summarized in Table 10. 

The titanium trichloride-diethylaluminum chloride catalyst converted butadiene to the cis-, trans,-trans-cyclododecatriene. Professor Wilke and co-workers found that the particular structure is influenced by coordination during cyclization between the transition metal and the growing diene molecules. Analysis of the influence of the ionicity of the catalyst shows effects on the oxidation and reduction of the alkyls and on the steric control in the polymerization. The lower valence of titanium is oxidized by one butadiene molecule to produce only a cis-butadienyl-titanium. Then the cationic chain propagation adds two trans-butadienyl units until the stereochemistry of the cis, trans, trans structure facilitates coupling on the dialkyl of the titanium and regeneration of the reduced state of titanium (Equation 14). 

Fig. 7-30. Examples of proposed leucochromophoric and chromophoric structures. Aryl-coumarones (1) and stilbene quinones (2) are thought to be formed from stilbenes after oxidation. Butadiene quinones (3) could arise from oxidation of hydroxyarylbutadienes being formed from phenolic pinoresinol structures during kraft or neutral sulfite pulping. Cyclization may yield intermediates which are further oxidized to cyclic diones (4). A resonance-stabilized structure (5) results from the corresponding condensation product formed during pulping. o-Quinoid structures (7) are oxidation products of catechols (6) formed during alkaline or neutral pulping processes.

Two potassium atoms transfer an electron each to butadiene forming a dianion transmetallation with o-xylene then gives the potassium-bonded carbanion, which inserts butadiene. A second transmetallation with o-xylene liberates the potassium-stabilized benzylcarbanion, which is the actual catalytic species and generates o-pentenyltoluene. This can then be cyclized to 1,5-dimethyltetralin, which, after dehydrogenation to the corresponding naphthalene and isomerization to the 2,6-isomer, affords 2,6-naphthalenedicarboxylic acid by oxidation. 

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