Acid halides hydrolysis

Section 19 12 Nitnles which can be prepared from primary and secondary alkyl halides by nucleophilic substitution with cyanide ion can be converted to car boxyhc acids by hydrolysis... 

Solid Superacids. Most large-scale petrochemical and chemical industrial processes ate preferably done, whenever possible, over soHd catalysts. SoHd acid systems have been developed with considerably higher acidity than those of acidic oxides. Graphite-intercalated AlCl is an effective sohd Friedel-Crafts catalyst but loses catalytic activity because of partial hydrolysis and leaching of the Lewis acid halide from the graphite. Aluminum chloride can also be complexed to sulfonate polystyrene resins but again the stabiUty of the catalyst is limited. 

Methylsuccinic acid has been prepared by the pyrolysis of tartaric acid from 1,2-dibromopropane or allyl halides by the action of potassium cyanide followed by hydrolysis by reduction of itaconic, citraconic, and mesaconic acids by hydrolysis of ketovalerolactonecarboxylic acid by decarboxylation of 1,1,2-propane tricarboxylic acid by oxidation of /3-methylcyclo-hexanone by fusion of gamboge with alkali by hydrog. nation and condensation of sodium lactate over nickel oxide from acetoacetic ester by successive alkylation with a methyl halide and a monohaloacetic ester by hydrolysis of oi-methyl-o -oxalosuccinic ester or a-methyl-a -acetosuccinic ester by action of hot, concentrated potassium hydroxide upon methyl-succinaldehyde dioxime from the ammonium salt of a-methyl-butyric acid by oxidation with. hydrogen peroxide from /9-methyllevulinic acid by oxidation with dilute nitric acid or hypobromite from /J-methyladipic acid and from the decomposition products of glyceric acid and pyruvic acid. The method described above is a modification of that of Higginbotham and Lapworth. ... 

Conversion of Acid Halides into Acids Hydrolysis Acid chlorides react with water to yield carboxylic acids. This hydrolysis reaction is a typical nucleophilic acyl substitution process and is initiated by attack of water on the acid chloride carbonyl group. The tetrahedral intermediate undergoes elimination of Cl and loss of H+ fo give the product carboxylic acid plus HC1. 

Conversion of Acid Halides into Esters Alcoholysis Acid chlorides react with alcohols to yield esters in a process analogous to their reaction with water to yield acids. In fact, this reaction is probably the most common method for preparing esters in the laboratory. As with hydrolysis, alcoholysis reactions are usually carried out in the presence of pyridine or NaOH to react with the HC1 formed. 

A more general method for preparation ofa-amino acids is the amidotnalmatesynthesis, a straightforward extension of the malonic ester synthesis (Section 22.7). The reaction begins with conversion of diethyl acetamidomalonate into an eno-late ion by treatment with base, followed by S 2 alkylation with a primary alkyl halide. Hydrolysis of both the amide protecting group and the esters occurs when the alkylated product is warmed with aqueous acid, and decarboxylation then takes place to vield an a-amino acid. For example aspartic acid can be prepared from, ethyl bromoacetate, BrCh CCHEt ... 

A number of approaches have been tried for modified halo-de-diazoniations using l-aryl-3,3-dialkyltriazenes, which form diazonium ions in an acid-catalyzed hydrolysis (see Sec. 13.4). Treatment of such triazenes with trimethylsilyl halides in acetonitrile at 60 °C resulted in the rapid evolution of nitrogen and in the formation of aryl halides (Ku and Barrio, 1981) without an electron transfer reagent or another catalyst. Yields with silyl bromide and with silyl iodide were 60-95%. The authors explain the reaction as shown in (Scheme 10-30). The formation of the intermediate is indicated by higher yields if electron-withdrawing substituents (X = CN, COCH3) are present. In the opinion of the present author, it is likely that the dissociation of this intermediate is not a concerted reaction, but that the dissociation of the A-aryl bond to form an aryl cation is followed by the addition of the halide. The reaction is therefore mechanistically not related to the homolytic halo-de-diazoniations. 

Compared with esters, acid halides and anhydrides are more reactive and are hydrolyzed more readily. It is interesting to note that there is a substantial lifetime for these acid derivatives in aqueous media. Acid halides dissolved in PhCl or in PhBr shaken at a constant rate with water shows that hydrolysis occurs at the boundary between the two liquid phases.35 The reaction of benzoyl chloride (PhCOCl) and benzoate ion with pyridine A-oxide (PNO) as the inverse phase-transfer catalyst yields both the substitution product (benzoic anhydride) and the... 

A useful approach for the preparation of chiral (3-aminophospho-nic acids from the naturally occurring a-amino acids has been reported.139 The overall scheme (Equation 3.4) involves formation of the phthalimide-acid halide from the starting a-amino acid followed by a Michaelis-Arbuzov reaction with triethyl phosphite to give the acylphosphonate. Complete reduction of the carbonyl group in three steps followed by hydrolysis of the ester and amide linkages provides the target material in very high yield without racemization (>99% ee). 

Acid-grade feldspar, aluminum fluoride production from, 2 357—358 Acid-grade fluorspar, 4 579, 580 analysis, 4 577t Acid halides, 12 188-190 Acid hydrolysis. See also Acidic hydrolysis of wood, 26 358 of wool, 26 376 Acid hydrolysis lignin, 15 21 Acidic catalysts, 10 556. See also Acid catalysts... 

Acidic gases, limestone reaction with, 15 33 Acidic halide catalysts, 12 167 Acidic hydrolysis, 10 502. See also Acid hydrolysis... 

The most frequently used method for the preparation of isoquinoline Reissert compounds is treatment of an isoquinoline with acyl chloride and potassium cyanide in water or in a dichloromethane-water solvent system. Though this method could be successfully applied in a great number of syntheses, it has also some disadvantages. First, the starting isoquinoline and the Reissert compound formed in the reaction are usually insoluble in water. Second, in the case of reactive acyl halides the hydrolysis of this reaction partner may became dominant. Third, the hydroxide ion present could compete with the cyanide ion as a nucleophile to produce a pseudobase instead of Reissert compound. To decrease the pseudobase formation phase-transfer catalysts have been used successfully in the case of the dichloromethane-water solvent system, resulting in considerably increased yields of the Reissert compound. To avoid the hydrolysis of reactive acid halides in some cases nonaqueous media have been applied, e.g., acetonitrile, acetone, dioxane, benzene, while utilizing hydrogen cyanide or trimethylsilyl cyanide as reactants instead of potassium cyanide. 

Acid-catalyzed hydrolysis of Reissert compounds results in an aldehyde, a formal reduction product of the acyl halide utilized in the Reissert compound formation (11). The mechanism of the reaction according to McEwen and Cobb (3), is shown in Scheme 2. 

Acid halides and anhydrides are so reactive that they react with water under neutral conditions. This can he a potential problem for the storage if these compounds since these compounds can he air (moisture) sensitive. Hydrolysis of these compounds can he avoided hy using dry nitrogen atmospheres and anhydrous solvents and reagents. 

Metal ions have been shown to catalyze the hydrolysis of phosphate esters, phosphoric and phosphonic acid halides, and various phosphoric acid anhydrides including acyl phosphates, pyrophosphate derivatives, and ATP. 

Rearrangement accompanying oxygenation was used to make other acid halides, and thence acids via hydrolysis, from bromofluoroalkenes, e. g. formation of 4 from 3 and 6 from 5. 

This chapter deals with the kinetics and mechanisms of the hydrolysis of carboxylic acid derivatives of general formula RCOX. These include carboxylic acid halides, amides, and anhydrides with small sections on carboxylic acid cyanides etc. Many recent developments in this field have been made with acid derivatives in which R is not an aliphatic or aromatic group, for example, carbamic acid derivatives, and these are reported where relevant, as are reactions such as ethanolysis, aminolysis, etc. where they throw light on the mechanisms of hydrolysis. 

However, detection of the tetrahedral intermediate in the addition of a nucleophile to an ester, acid halide, amide or anhydride must be adduced from kinetic evidence, in particular the evidence of oxygen exchange in such an intermediate. Such tracer work has established the presence of symmetrical addition compounds in the hydrolysis of esters23, amides and acid chlorides24. Since the attempts to detect such intermediates have played a considerable part in the development of hydrolysis studies, it is worthwhile considering this point in some detail. 

Two further properties which must be intimately related with the problems of the tetrahedral intermediate are the solvent isotope effect and the entropy of activation for the hydrolysis of RCOX. Table 2 lists the values of entropies of activation for the neutral hydrolyses of esters, anhydrides, and acid chlorides. Values of —30 to — 40 eu are common to the hydrolyses of esters and anhydrides, but for acid halides the value is down to---10 eu. The only slight... 

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