Alkyl iodides carbonylation

Benzodithioles 285 (R1 = H) and 7,8-dimethyl-l,5-dihydro-2,4-benzodithiepins286 (R = H) have been used as precursors of formyl and acyl anion derivatives. The lithiation of compounds 285 takes place at —30 °C with n-BuLi and these anions are stable for long periods of time at this temperature454. They react with alkyl iodides, carbonyl compounds and epoxides, the addition to cyclohex-2-enone taking place at the carbonyl group. The deprotection has also been carried out with mercury(II) oxide and BF3 OEt2-... 

In a new procedure, several 3-substituted diazepam derivatives (124) have been prepared, in moderate to good yields, by allowing metallated diazepams (123) to react with alkyl iodides, carbonyl compounds, or esters. Two equivalents of lithium di-isopropylamide (LDA) were required to produce an equilibrium concentration of (123) that was sufficiently high for synthetic use. ... 

In the total synthesis of zearaienone (451), the ester 450 was prepared by the carbonylation of the crowded aryl iodide 448. The alkyl iodide moiety in the alcohol molecule 449 is not attacked[306]. Methyl trifluoromethacrylate (453) was prepared by the carbonylation of 3,3,3-trifluoro-2-bromopropylcne (452), The carbonylation in the presence of alkylurea affords 454. which is converted into the trifluoromethyluracil 455[307],... 

The carbonylation of aryl iodides in the presence of alkyl iodides and Zn Cu couple affords aryl alkyl ketones via the formation of alkylzinc species from alkyl iodides followed by transmetallation and reductive elimination[380]. The Pd-catalyzed carbonylation of the diaryliodonium salts 516 under mild conditions in the presence of Zn affords ketones 517 via phenylzinc. The a-diketone 518 is formed as a byproduct[381],... 

Particularly alkyl halides which have a perfluoroalkyl group at the /3-position undergo smooth carbonylation. Probably the coordination of fluorine to form a five-membered chelate ring accelerates the reaction. Double carbonylation to give the a-keto amide 915 is possible in Et NH with the fluorine-bearing alkyl iodide 914[769,770]. The ester 917 is obtained by the carbonylation of the /3-perfluoroalkyl iodide 916 in ethanol. 

Alkyl ketones can be prepared by the carbonylation of alkyl iodides in the presence of organoboranes. The carbonylation of iodocyclohexane with 9-octyl-9-BBN at 1 atm gives cyclohexyl octyl ketone in 65% yield[386]. This reaction is treated in Section 1.1.3.3. Methyl o-methylacetoacetate (919) is obtained by the reaction of the 2-bromopropionate 918, which has a /9-hydrogen, with CO and Me4Sn. PhjAs as a ligand gives better results than Ph3P[771]. 

C-C bonds can be formed by reaction with alkyl iodides or more usefully by reaction with metal carbonyls to give aldehydes and ketones e.g. Ni(CO)4 reacts with LiR to form an unstable acyl nickel carbonyl complex which can be attacked by electrophiles such as H+ or R Br to give aldehydes or ketones by solvent-induced reductive elimination ... 

Rhodium catalyzed carbonylations of olefins and methanol can be operated in the absence of an alkyl iodide or hydrogen iodide if the carbonylation is operated in the presence of iodide-based ionic liquids. In this chapter, we will describe the historical development of these non-alkyl halide containing processes beginning with the carbonylation of ethylene to propionic acid in which the omission of alkyl hahde led to an improvement in the selectivity. We will further describe extension of the nonalkyl halide based carbonylation to the carbonylation of MeOH (producing acetic acid) in both a batch and continuous mode of operation. In the continuous mode, the best ionic liquids for carbonylation of MeOH were based on pyridinium and polyalkylated pyridinium iodide derivatives. Removing the highly toxic alkyl halide represents safer, potentially lower cost, process with less complex product purification. 

Historically, the rhodium catalyzed carbonylation of methanol to acetic acid required large quantities of methyl iodide co-catalyst (1) and the related hydrocarboxylation of olefins required the presence of an alkyl iodide or hydrogen iodide (2). Unfortunately, the alkyl halides pose several significant difficulties since they are highly toxic, lead to iodine contamination of the final product, are highly corrosive, and are expensive to purchase and handle. Attempts to eliminate alkyl halides or their precursors have proven futile to date (1). 

Recently, Eastman Chemical Company reported that ionic liquids can be successfully employed in a vapor take-off process for the carbonylation of methanol to acetic acid in the presence of rhodium and methyl iodide (3). While attempting to extend this earlier work to the carbonylation of ethylene to propionic acid, we discovered that, when using ionic liquids as a solvent, acceptable carbonylation rates could be attained in the absence of any added alkyl iodide or hydrogen iodide (4). We subsequently demonstrated that the carbonylation of methanol to acetic acid could also be operated in the absence of methyl iodide when using ionic liquids (5). 

Ethylene Carbonylation. The classical rhodium catalyzed carbonylation of ethylene to propionic acid (Eqn. 1) used ethyl iodide or HI as a co-catalyst (6). In the presence of excess ethylene and CO the process could proceed further to propionic anhydride (Eqn. 2). While additional products, such as ethyl propionate (EtC02Et), diethyl ketone (DEK), and ethanol were possible (See Eqns. 3-5), the only byproduct obtained when using a rhodium-alkyl iodide catalyst was small amounts (ca. 1-1.5%) of ethyl propionate. (See Eqns. 3-5.)... 

A comprehensive kinetic, spectroscopic, and analysis study into the Rh-catalyzed carbonylation of ROH (R = Me, Et, Pr) has been reported.4,5 In all cases, the reaction rate is first order in both [Rh] and added [HI] and independent of CO pressure. The only Rh species observed under catalytic conditions was (1). The rates of carbonylation decreased in the stated order of R, with relative rates of 21 1 0.47, respectively at 170 °C. All the data are consistent with rate-determining nucleophilic attack by the Rh complex anion on the corresponding alkyl iodide. 

Reactions of alcohols, ethers, and aliphatic halides with carbon monoxide were described as far back as 1948-1953 (173, 195). High pressure and temperature were required, however, for these processes. The use of alkaline media allowed carbonylation of alkyl iodides under mild conditions (example 22, Table VII). More recently, carbonylation of alkyl-nickel complexes was reported (example 26, Table VII). 

In addition to small amounts of methane, acetaldehyde or acetic anhydride can be generated in substantial quantities depending on conditions. However, they are not present simultaneously in any appreciable quantity. Acetic anhydride and acetaldehyde must be competitively formed (equation 6), and subsequently react with each other to form EDA (step C). This reaction (step C) is generally catalyzed by protic acids (2-4). The reaction solution for reductive carbonylation is quite acidic HI is an intermediate generated under reaction conditions of high alkyl iodide concentration and hydrogen pressure. The thermodynamic equilibrium of this condensation is quite favorable for diester formation existence of an abundance of either anhydride or aldehyde in the presence of the other is not found. Yields of stoichiometric preparations are in excess of 95%... 

Reaction rates have first-order dependence on both metal and iodide concentrations. The rates increase linearly with increased iodide concentrations up to approximately an I/Pd ratio of 6 where they slope off. The reaction rate is also fractionally dependent on CO and hydrogen partial pressures. The oxidative addition of the alkyl iodide to the reduced metal complex is still likely to be the rate determining step (equation 8). Oxidative addition was also indicated as rate determining by studies of the similar reactions, methyl acetate carbonylation (13) and methanol carbonylation (14). The greater ease of oxidative addition for iodides contributes to the preference of their use rather than other halides. Also, a ratio of phosphorous promoter to palladium of 10 1 was found to provide maximal rates. No doubt, a complex equilibrium occurs with formation of the appropriate catalytic complex with possible coordination of phosphine, CO, iodide, and hydrogen. Such a pre-equilibrium would explain fractional rate dependencies. 

A prototypical study for this section has been obtained as early as in 1983 for carbonylative cross-coupling of the mixture of aryl iodide and alkyl iodide in the presence of Zn metal and palladium catalyst. This system apparently works due to differences of reactivity of aryl versus alkyl iodide toward metallation by Zn. Further studies were rather scarce to involve only preformed functionalized alkylzincs. Carbonylative cross-coupling of functionalized organozinc reagents with allylic esters and GO (1 atm) can be carried out in THF in the presence of HMPA, which suppresses side-reactions (Scheme 4). ... 

Tris(dimethylamino)sulfonium difluo-rotrimethylsilicate, 336 Xenon(II) fluoride, 345 Alkyl bromides Potassium permanganate, 258 Sodium bromide, 46 Tetraethylammonium bromide, 46 Alkyl iodides Aluminum iodide, 17 Potassium permanganate, 258 Sodium iodide, 46 Tetraethylammonium iodide, 46 Alkynes (see also Acetylenic carbonyl compounds, Diynes, Enynes, Propar-gyl alcohols)... 

In an indirect electrochemical process, vitamin B,2 has been used as catalyst for the cathodic alkylation of a,p-unsaturated carbonyl compounds by alkyl iodides as exemplified in the formation of (+)- X0-brevicomine [30] ... 

Alternatively, a more nucleophilic anionic reagent can be generated by selective cleavage of a single trimethylsilyl group with methyl lithium-lithium bromide complex. This 1ithiobutadlyne derivative will react with electrophiles such as carbonyl compounds or primary alkyl iodides. 2... 

Scheme 6.33 illustrates an example of some zinc-induced three-component coupling reactions of alkyl iodides, electron-deficient alkenes, and carbonyl compounds [51]. In this instance, the isopropyl radical is generated by a one-electron reduction of isopropyl iodide followed by elimination of iodide ion. The resulting radical then adds to acrylonitrile to form an a-cyano alkyl radical, which is con-... 

A similar three-component transformation can be achieved using triethylborane-induced radical reactions (Scheme 6.34) [53]. On exposure to air, triethylborane generates the ethyl radical, which abstracts iodine from alkyl iodides to generate the t-butyl radical. Addition of the resulting t-butyl radical to methyl vinyl ketone produces a radical a to the carbonyl group, which is trapped by triethylborane to form a boron enolate with the liberation of ethyl radical, thus creating a chain. 

Even the sterically hindered 2,6-disubstituted aryl iodide 443 is carbonylated smoothly to give 445. Alkyl iodide present in the alcoholic component 444 remains intact under the carbonylation conditions. This carbonylation reaction is a key reaction in the synthesis of zearalenone (446) [216]. Optimal conditions for technical synthesis of the anthranilic acid derivative 448 from bromide 447 has been studied, and it has been found that A-acetyl protection of 447, which has a chelating effect, is important [217]. Cheaply available chlorides are rather inert [13]. The carbonylation of chloride 449 in the presence of DBU and Nal gives the amide 450 [218],... 

ROH - RI,1 Reaction of I2 (1 equiv.) with BH3 QHsNfCjHsJj provides a diiodoborane amine complex in situ that converts alcohols into alkyl iodides in 62-86% yield. It also effects reductive iodination of carbonyl compounds. 

Kondo and coworkers studied the alkoxycarbonylation of alkyl iodides 152 catalyzed by a large number of metal carbonyl complexes [258]. Among them 4 mol% Re2(CO)io was highly active giving 77% yield of ester 154 (cf. Fig. 41). 

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