Esterification bromide

In the same way, furanothiepin 6 is obtained by esterification of the corresponding diacid, then converted with methylmagnesium bromide to the highly reactive diol 7, which gives a eycloadduct with iV-phenylmaleimide in 65% overall yield67 (see Section 2.2.5.). 

The method used is described by Drysdale, Stevenson, and Sharkey.4 The methyl ester of butadienoic acid has not been described previously, but the free acid contaminated by 2-bu-tynoic acid has been prepared by Wotiz, Matthews, and Lieb 5 by carbonation of propargylmagncsium bromide. Ethyl butadienoate has been prepared by Eglinton, Jones, Mansfield, and Whiting by alkali-catalyzed isomerization of ethyl 3-butynoate prepared from 3-butynol by chromic acid oxidation and esterification. 

These acid-catalyzed C-glycosylations were successfully extended to the D-ribofuranose series by Sorm and coworkers,148 who utilized the reaction in the first reported synthesis of showdomycin. Thus, treatment of 2,3,5-tri-0-benzoyl-/3-D-ribofuranosyl bromide (81) with 1,2,5-trimethoxybenzene in the presence of zinc oxide gave 2,4,6-trimethoxy-l-(2,3,5-tri-0-benzoyl-/3-D-ribofuranosyl)benzene (196). Ozonolysis of the corresponding acetate derivative, followed by esterification, gave the highly functionalized C-/3-I>ribofuranosyl derivative (197), which was used as a key intermediate in the synthesis of showdomycin (see Section III,l,b). 

Several total syntheses of antirhine (11) and 18,19-dihydroantirhine (14) have been developed during the last decade. Wenkert et al. (136) employed a facile route to ( )-18,19-dihydroantirhine, using lactone 196 as a key building block. Base-catalyzed condensation of methyl 4-methylnicotinate (193) with methyl oxalate, followed by hydrolysis, oxidative decarboxylation with alkaline hydrogen peroxide, and final esterification, resulted in methyl 4-(methoxycar-bonylmethyl)nicotinate (194). Condensation of 194 with acetaldehyde and subsequent reduction afforded nicotinic ester derivative 195, which was reduced with lithium aluminum hydride, and the diol product obtained was oxidized with manganese dioxide to yield the desired lactone 196. Alkylation of 196 with tryptophyl bromide (197) resulted in a pyridinium salt whose catalytic reduction... 

Chau and Terry [146] reported the formation of penta-fluorobenzyl derivatives of ten herbicidal acids including 4-chloro-2-methyl-phenoxy acetic acid [145]. They found that 5h was an optimum reaction time at room temperature with pentafluorobenzyl bromide in the presence of potassium carbonate solution. Agemian and Chau [147] studied the residue analysis of 4-chloro-2-methyl phenoxy acetic acid and 4-chloro-2-methyl phenoxy butyric acid from water samples by making the pentafluorobenzyl derivatives. Bromination [148], nitrification [149] and esterification with halogenated alcohol [145] have also been used to study the residue analysis of 4-chloro-2-methyl phenoxy acetic acid and 4-chloro-2-methyl phenoxybutyric acid. Recently pentafluorobenzyl derivatives of phenols and carboxylic acids were prepared for detection by electron capture at very low levels [150, 151]. Pentafluorobenzyl bromide has also been used for the analytical determination of organophosphorus pesticides [152],... 

The kinetics of the esterification of potassium p-nitrobenzoate by benzyl bromide in dichloromethane-water catalysed by dicyclohexyl-18-crown-6 ([20] + [21]) has been studied by Wong (1978). At low catalyst concentrations (e.g. 5.0 x 10 3 M) he found that 22% of the product was formed by the SN1 and 78% by the SN2 mechanism. Higher catalyst concentrations increased the salt concentration in the organic phase, and the contribution of the SN1 mechanism becomes negligibly small. 

The methylenemalonate moiety was used as an N-protecting group at the esterification of amino acids. After the esterification of the carboxyl group with the appropriate alkyl bromide in acetone in the presence of... 

Methyl fi-bromopropionate has been prepared by the esterification of /3-bromopropionic acid with methyl alcohol alone1 and through the use of hydrogen bromide as a catalyst,2 and by the direct addition of hydrogen bromide to methyl acrylate.2... 

Meanwhile attempts to find an air oxidation route directly from p-xylene to terephthalic acid (TA) continued to founder on the relatively high resistance to oxidation of the /Moluic acid which was first formed. This hurdle was overcome by the discovery of bromide-controlled air oxidation in 1955 by the Mid-Century Corporation [42, 43] and ICI, with the same patent application date. The Mid-Century process was bought and developed by Standard Oil of Indiana (Amoco), with some input from ICI. The process adopted used acetic acid as solvent, oxygen as oxidant, a temperature of about 200 °C, and a combination of cobalt, manganese and bromide ions as catalyst. Amoco also incorporated a purification of the TA by recrystallisation, with simultaneous catalytic hydrogenation of impurities, from water at about 250 °C [44], This process allowed development of a route to polyester from purified terephthalic acid (PTA) by direct esterification, which has since become more widely used than the process using DMT. 

The combined catalysis by 18-crown-6 and tetra-n-butylammonium bromide produces higher yields in shorter reaction times than either of the catalysts separately (Table 3.7) [21] and almost quantitative yields have been reported for solid solid liquid triphase catalysed esterification using silica impregnated with tetramethylammonium chloride [22]. 

Combined crown ether and quaternary salt catalysis of the esterification of benzoic acid with phenacyl bromide... 

In the DMT process, the esterification is done by feeding a slurry of TPA crystals in methanol to a reactor with a catalyst of sulfuric acid at 220°F and 50 psi. DMT forms and can be purified by distillation. Yields exceed 95%, based on the TPA that ends up as DMT. In some later designs resulting in less severe operating conditions, MEK or acetaldehyde have been used as promoters in place of sodium bromide. 

The first three retrosynthetic cleavages are formation of the C7-C8 aldol by intramolecular chromium-Reformatsky reaction of linear precursor 51, esterification between northern and southern half building blocks and Wit-tig reaction of phosphonium salt 52 known from Mulzer s work [85] and northern half precursor 53. The final disconnections were placed at the C2-C3 aldol in 51 (again to be formed by chromium-Reformatsky reaction, here between bromoacetimide 56 and aldehyde 57) and the C14-C15 bond by alkylation of acetoacetate 54 with neryl bromide 55. 

The ester derivative of pyrrolo-benzoxazepine 403 (Scheme 84) has been transformed into ketone 404 with methyl lithium, while ester 406 was synthesized by esterification with acetyl bromide of alcohol 405, prepared by LAH reduction of 403 (1996JMC3435). 

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