Methyl acetate, hydroformylation

Methyl acetate probably originates from the reaction of methanol with the intermediate cobalt-acyl complex. The reaction leading to the formation of acetaldehyde is not well understood. In Equation 8, is shown as the reducing agent however, metal carbonyl hydrides are known to react with metal acyl complexes (20-22). For example, Marko et al. has recently reported on the reaction of ri-butyryl- and isobutyrylcobalt tetracarbonyl complexes with HCo(CO) and ( ). They found that at 25 °C rate constants for the reactions with HCo(CO) are about 30 times larger than those with however, they observed that under hydroformylation conditions, reaction with H is the predominant pathway because of the greater concentration of H and the stronger temperature dependence of its rate constant. The same considerations apply in the case of reductive carbonylation. Additionally, we have found that CH C(0)Co(C0) L (L r PBu, ... 

Industrial (BASF) syntheses of vitamin A and vitamin A aldehyde have been accomplished utilizing the aldehydes obtained from allyl acetate hydroformylation.22 Either aldehyde (10) or (11) reacts with the same phosphorus ylide to give vitamin A or retinal (Scheme 4). Hydroformylation of 3-methyl-2-butenyl acetate gives a high yield of 2-formyl-3-methylbutyl acetate. Elimination of acetic acid followed by isomerization provides trimethylacrylaldehyde, which is an intermediate in the synthesis of irones (Scheme 5). 

Industrial applications are toluene and xylene oxidation to acids, oxidation of ethene to aldehyde, carbonylation of methanol and methyl acetate, polymerization over metallocenes (Figure 2.2), hydroformylation of alkenes, etc. 

An early attempt to hydroformylate butenediol using a cobalt carbonyl catalyst gave tetrahydro-2-furanmethanol (95), presumably by aHybc rearrangement to 3-butene-l,2-diol before hydroformylation. Later, hydroformylation of butenediol diacetate with a rhodium complex as catalyst gave the acetate of 3-formyl-3-buten-l-ol (96). Hydrogenation in such a system gave 2-methyl-1,4-butanediol (97). 

The cobalt-catalyzed hydroformylation of acrolein diacetate in ethanol proceeded in a complicated fashion. The products obtained are listed in Table XXVI. These products are rationalized by the following sequence The initial products formed were m-aldehyde (l,l-diacetoxy-3-formylpro-pane, ca. 60%), isoaldehyde (1,1 -diacetoxy-2-formylpropane, 5-10%) and propionaldehyde diacetate, ca. 5%. In the alcohol solvent, the aldehydes were converted to the corresponding acetals. A portion of the n-aldehyde was converted to 2,5-diethoxytetrahydrofuran by acid catalysis, and the isoaldehyde was thermally decomposed to 2-methyl-3-acetoxyacrolein. 

Rhodium( I)-catalyzed hydroformylation of cyclic enol acetals 1 leads to acetal-protected syn-3,5-dihydroxyalkanals 2 with extraordinarily high levels (>50 1) of diastereoselectivity (Scheme 5.2) [2]. The diastereoselectivity cannot be ascribed to any obvious steric bias, and serves as a powerful demonstration that the hydroformylation reaction may be subject to exquisite stereoelectronic control. Indeed, while the addition of a pseudo-axial methyl group to the acetal carbon (as in acetonide 3) has a deleterious effect on the rate of the reaction, the sy -diastereomer 4 is still produced selectively, in what is surely a contra-steric hydroformylation reaction. 

Rhodium-catalyzed hydroformylation of 2-amino-/V-(but-3 -enyl)- and -A-(3 -rnethylbut-3 -enyi)benzylamines (381) in the presence of rho-dium(II) acetate dimer and triphenylphosphine in deoxygenated ethyl acetate gave mixtures of 5,5a,6,7,8,9-hexahydro-llH-pyrido[2,l-b]quinazo-line (382), isomeric 6-methyl-5,5a,6,7,8,10-hexahydropyrrolo[2,l-b]quina-zolines (383), and 6-methyl-6,7,8,10-tetrahydropyrrolo[2,l-ft]quinazoline (384), as well as a stereoisomeric mixture of 7-methyl-5,5a,6,7,8,9-hexahy-dro-ll//-pyrido[2,l-b]quinazolines (385) and 15% of 7-methyl-6,7,8,9-tetrahydro-llH-pyrido[2,l-fr)quinazolme (386), (95AJC2023). When the bulky tricyclohexylphosphine was used instead of triphenylphosphine, a 3 7 mixture of compounds 382 and 383 and a 3 1 mixture of isomeric 385 were formed. 

Rhodium-catalyzed hydroformylation of -(substituted amino)benzyl-amines (387, X = H2) and -(substituted amino)benzamides (387, R = H, X = O) in the presence of rhodium(II) acetate dimer and triphenylphos-phine in deoxygenated ethyl acetate gave a 7 3 mixture of 1,2,3,4,4 ,5-hexahydro-6//-pyrido[l,2-a]quinazolines (388, X = H2,0) and isomeric 3-methyl-l,2,3,3fl,4,5-hexahydropyrrolo[l,2-a]quinazolines (389, X = H2, O) (94AJC1061). The methyl derivative of benzylamine 387 (R = Me, X = H2) afforded a mixture of diastereoisomers 390 and 391 (X = H2). Their ratio depended on the reaction time. Longer reaction times gave more 391 (X = H2), containing the methyl group in an equatorial position. Compound 390 isomerized into 391 (X = H2), under the aforementioned conditions. The benzamide derivative (387, R = Me, X = O) yielded only one isomer (391, X = O), independent of the reaction period. 

Rh2Cl2(CO)4] together with DIOP, benzyl(methyl)phenylphosphine or neomenthyl-diphenylphosphine has been investigated in the hydroformylation of vinyl acetate (equation 66). 

There are two new approaches to the 9-carboxylic acid 613, R = H. One consists in the reaction of dichlorocarbene with 4-methylacetophenone. The initially formed dichloroepoxide reacted with sodium hydroxide, and the main product from the reaction was the hydroxy acid 614, which underwent dehydration to 613 (R = H). The latter formed dimers in boiling water. Methyl (4-methylphenyl)acetate (615) reacted with formaldehyde, and the product 616 was dehydrated to 613 (R = Me). Hydrogenation over rhodium then gave the ester 617, which is also the product of hydroformylation of 615. " ... 

Recently, rhodium/poly(enolate-co-vinyl alcohol-co-vinyl acetate) catalysts have been developed for the biphasic hydroformylation of aliphatic alkenes and applied to the selective hydroformylation of functionalized alkenes [16], Although the conversions were low (< 25%), excellent selectivities for the hydroformylation of n-bu-tyl vinyl ether and methyl 3,3-dimethylpenten-4-onate can be achieved with such water-soluble polymer-anchored rhodium catalysts. For instance, the hydroformylation of methyl 3,3-dimethylpenten-4-onate gives only the linear aldehyde. 

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