Acid chlorides, reactions tables

Reaction times and temperatures vary, depending on the substrate acid chloride (see Table I). 

Acid chlorides are generally more reactive than the parent acids, so polyester formation via reaction 5 in Table 5.3 can be carried out in solution and at lower temperatures, in contrast with the bulk reactions of the melt as described above. Again, the by-product molecules must be eliminated either by distillation or precipitation. The method of interfacial condensation, described in the next section, can be applied to this type of reaction. 

Yamase and Goto406 determined first- and second-order rate coefficients for the aluminium chloride-catalysed reaction of halide derivatives of benzoic acid (lO5 = F, 1.73 Cl, 4.49 Br, 4.35 I, 0.81) and phenylacetic acid (105fc2 = F, 12 Cl, 21 Br, 9 I, 6) with benzene. The maxima in the rates for the acid chloride are best accommodated by the assumption that a highly (but not completely) polarised complex takes part in the transition state. Polarisation of such a complex would be aided by electron supply, and consistently, the acetyl halides are about a hundred times as reactive as the benzoyl compounds (see p. 180, also Tables 105 and 108). 

Chloroaluminate ionic liquids (typically a mixture of a quaternary ammonium salt with aluminum chloride see Table 6.9) exhibit at room temperature variable Lewis acidity and have been successfully used as solvent/catalyst for Diels-Alder reactions [57]. The composition of chloroaluminate ionic liquids can vary from basic ([FMIM]C1 or [BP]C1 in excess) to acidic (AICI3 in excess) and this fact can be used to affect the reactivity and selectivity of the reaction. The reaction of cyclopentadiene with methyl acrylate is an example (Scheme 6.31). 

Further molecular compounds have been prepared from T8l(CH2)3NH3Cl]8 and T8[(CH2)3NH2]s using reactions involving olefins (Table 27, entries 1, 4, and 8), acid chlorides (Table 27, entries 3 and 7), and phosphines (Table 27, entries 9 and 10). Further elaboration of the resulting compounds can also be carried out without the POSS core being degraded (Table 27, entries 2 and 6). 

Multi-armed polymers with a cyclotriphosphazene core XI and XII have been synthesized from the reaction of polyethylene glycol monomethyl ethers with acid chlorides of hexakis(3,5-dicarboxyphenoxy) and hexakis(4-carboxyphe-noxy) cyclotriphosphazenes. Their complexes with LiC104 were investigated, and their maximum conductivities are reported in Table 17 [621]. 

Tin and HCl reduce out the ben/.ylic OH from (43) in high yield.The Mannich base (45) decomposes to (41) simply on heating. Cyanide addition gives (46) which can be hydrolysed to (40), but a short cut is to hydrolyse to amide (47) and reduce out the carbonyl group by the Clemmensen method (Table T 24.1). Under these conditions the amide is hydrolysed to the acid. Cyclisation to (38) occurs with strong acid, acid anhydrides, or by AlClg-catalysed reaction of the acid chloride. 

Induced oxidation of alcohols by hydrogen peroxide was studied by Kolthoff and Medalia . According to their measurements the value of F-, increases with the increase in the concentration of ethanol, while it decreases with increase in the acid concentration (see Table 16). In acetic acid medium the value of F[ is considerably lower. Chloride ions effectively suppress the induced oxidation of alcohols. The main product of the oxidation of ethanol is acetaldehyde which can be further oxidized to acetic acid. The data on the induced oxidation of alcohol (H2A) can be interpreted by reactions (53), (98), (99) and (57). 

Rearrangement of acetylenic sulphenates to the allenic sulphoxides 151 was discovered when the synthesis of propargylic ester of trichloromethanesulphenic acid 152 was attempted (equation 86). This reaction is of general scope and gives very good yields of allenic sulphoxides (Table 14) from structurally diverse cohols and various sulphenyl chlorides Reaction of alkynols 153 with benzenesulphenyl chloride in the presence... 

Suitable reagents for derivatizing specific functional groups are summarized in Table 8.21. Many of the reactions and reagents are the familiar ones used in qualitative analysis for the characterization of organic compounds by physical means. Alcohols are converted to esters by reaction with an acid chloride in the presence of a base catalyst (e.g., pyridine, tertiary amine, etc). If the alcohol is to be recovered after the separation, then a derivative which is fairly easy to hydrolyze, such as p-nltrophenylcarbonate, is convenient. If the sample contains labile groups, phenylurethane derivatives can be prepared under very mild reaction conditions. Alcohols in aqueous solution can be derivatized with 3,5-dinitrobenzoyl chloride. 

Water is always one product of a neutralization reaction. The other product is a salt. In the reaction of hydrochloric acid and sodium hydroxide, the salt is sodium chloride, which is, literally, table salt. Not all acid-base reactions make sodium chloride, but they do make a salt. Salts are ionic compounds. An ionic compound is a compound that is made up of cations (positively... 

However, because CDI reacts with HC1 to give phosgene (COCl2), reaction of the carboxylic acid with CDI must be complete before treatment with hydrochloric acid is undertaken. The yield of an acid chloride prepared by this one-pot reaction is comparable to those reported in Table 13-2. In general, acid chlorides are formed at room temperature within a few minutes. 

Catalysis in Transacylation Reactions. The principal objective of the study was to evaluate 4 as an effective organic soluble lipophilic catalyst for transacylation reactions of carboxylic and phosphoric acid derivatives in aqueous and two-phase aqueous-organic solvent media. Indeed 4 catalyzes the conversion of benzoyl chloride to benzoic anhydride in well-stirred suspensions of CH2CI2 and 1.0 M aqueous NaHCC>3 (Equations 1-3). The results are summarized in Table 1 where yields of isolated acid, anhydride and recovered acid chloride are reported. The reaction is believed to involve formation of the poly(benzoyloxypyridinium) ion intermediate (5) in the organic phase (Equation 1) and 5 then quickly reacts with bicarbonate ion and/or hydroxide ion at the interphase to form benzoate ion (Equation 2 and 3). Apparently most of the benzoate ion is trapped by additional 5 in the organic layer or at the interphase to produce benzoic anhydride (Equation 4), an example of normal phase-... 

Table 7 Reaction of silver acetylenide 239 with acid chlorides...

The reactivity of acylzirconocene chlorides towards carbon electrophiles is very low, and no reaction takes place with aldehydes at ambient temperature. In the reaction described in Scheme 5.12, addition of a silver salt gave the expected product, albeit in low yield (22—34%). The yield was improved to 79% by the use of a stoichiometric amount of boron trifluoride etherate (BF3OEt2) (1 equivalent with respect to the acylzirconocene chloride) at 0 °C. Other Lewis acids, such as chlorotitanium derivatives, zinc chloride, aluminum trichloride, etc., are less efficient. Neither ketones nor acid chlorides react with acylzirconocene chlorides. In Table 5.1, BF3 OEt2-mediated reactions of acylzirconocene chlorides with aldehydes in CH2C12 are listed. 

Some of the reactions (e.g., that of dimethylaluminum chloride in Table 2) involve redistribution of alkyl and halide groups between the metals. The boronic acids, ArB(OH>2, prepared by Sn/B transmetallation, have been used in Suzuki coupling reactions. It is remarkable that the bistributyltin derivative of 1,1 -binaphthyl undergoes... 

The reaction of acylsilanes with acid chlorides in the presence of A1C13 leads to furans (Table 9.41) [45]. In these reactions an acyl cation initiates the addition with ensuing silyl migration yielding an intermediate vinyl cation. Attack of the carbonyl oxygen followed by proton loss affords the observed products (Scheme 9.16). An analogous reaction with nitrosyl fluoroborate provides a route to oxazoles (Table 9.42) [65]. The nitrosyl cation serves as the electrophile in this application. 

Table 1. Sample Results for the Modification of Polymers Through Reaction with Acid Chlorides. 

Derivatives (Table I) formed by the reaction of the chosen polysaccharide with an isocyanate or acid chloride are carbamates and esters respectively. However, chitin or poly[(1+4)(N-acetyl-2-amino-2-deoxy-f3-glucopyranose)] actually used in this experiment contains approximately 16% free amine groups which can form urea and amide derivatives with the above reagents. 

Catalysed reaction of acid chlorides and anhydrides with alcohols and phenols (Table 3.11)... 

An interesting preparation of alkyl carboxylates in high yield (Table 3.14) from the sodium salt of the carboxylic acids under mild phase-transfer catalytic conditions involves their reaction with alkyl chlorosulphate [50] and has been used with success in the preparation of alkyl esters derived from p-lactam antibiotics. The procedure is also excellent for the production of chloromethyl esters, particularly where the carboxylic acids will not withstand the classical Lewis acid-catalysed procedure using an acid chloride and formaldehyde, or where the use of iodochloromethane [51] results in the formation of the bis(acyloxy)methane. The procedure has been applied with some success to the synthesis of chloromethyl A-protected a-amino carboxylates [52],... 

Azetidones (p-lactams) are generally obtained in high yield from (3-halopropion-amides (Table 5.18) and the low yield from the reaction of N-phenyl (3-chloropropi-onamide can be reconciled with the isolation of A-phenyl acrylamide in 58% yield [34]. The unwanted elimination reaction can be obviated by conducting the cyclization in a soliddiquid system under high dilution [35, 36]. Azetidones are also formed by a predominant intramolecular cyclization of intermolecular dimerization to yield piperazine-2,5-diones, or intramolecular alkylation to yield aziridones. Aone-pot formation of azetidones in 45-58% yield from the amine and P-bromocarboxylic acid chloride has also been reported [38]. 

The present procedure4 is an especially effective method for the synthesis of esters of aromatic acids and hindered tertiary alcohols or of acid-labile alcohols such as 2,2-diphenylethanol. The yields are excellent, and the reaction procedure is simple. The method is illustrated by the preparation of /-butyl p-toluate, a compound that could not be prepared by a conventional method0 of esterification involving the acid chloride and /-butanol in the presence of dimothylaniline. Examples of esters prepared by this method are illustrated in Table I. 

The ortho ester function is quite stable under neutral and basic conditions and is resistant to catalytic reduction [141]. However, acyl substituents with acid chloride [142] are reduced to aldehyde, and unsaturated centers [143-145] are saturated. The acyl side chain can also undergo the usual addition and substitution reactions without affecting the ortho ester function [145-147]. (See Eqs. 40, 45-47, and Table VII.)... 

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