Ester diazoacetates

Diazoacetic esters. Diazoacetic esters are prepared from reaction of bromoacetic esters and TsNHNHTs and DBU (base) in THF at 0°. 

In an asymmetric version, sulfide 271 shows the best results (Table 7.23). However, any reduction of the amount of catalyst is negatively reflected in the yield of the reaction [175, 177]. With ester diazoacetates the formation of ds-product is favoured (Scheme 7.49) [177]. 

Hydrazine [302-01-2] (diamide), N2H4, a colorless liquid having an ammoniacal odor, is the simplest diamine and unique in its class because of the N—N bond. It was first prepared in 1887 by Curtius as the sulfate salt from diazoacetic ester. Thiele (1893) suggested that the oxidation of ammonia (qv) with hypochlorite should yield hydrazine and in 1906 Raschig demonstrated this process, variations of which constitute the chief commercial methods of manufacture in the 1990s. 

From Diazo Compounds via 1,3-Dipolar Cycloaddition. This method has been utilized widely in heterocychc chemistry. Pyrazohne (57) has been synthesized by reaction of ethyl diazoacetate (58) with a,P-unsaturated ester in the presence of pyridine (eq. 12) (42). 

Furan and thiophene undergo addition reactions with carbenes. Thus cyclopropane derivatives are obtained from these heterocycles on copper(I) bromide-catalyzed reaction with diazomethane and light-promoted reaction with diazoacetic acid ester (Scheme 41). The copper-catalyzed reaction of pyrrole with diazoacetic acid ester, however, gives a 2-substituted product (Scheme 42). 

Decomposition of the diazoacetic ester (548) to the keto carbene (549) is promoted by copper(II) trifluoromethanesulfonate. In the presence of nitriles, 1,3-dipolar addition to the nitrile occurred giving the oxazole (550) (75JOM(88)ll5) (see also Section 4.03.8.1). 

Azulene (2) A mixture of 2-isopropyl-4,7-climethylindane 1 (200 g, 1.91 mol) and ethyl diazoacetate (50 g, 0.5 mol] was heated for 1 h at 130°C. Vacuum distillation and recovery ol 1 (160 g) gave a brown residue which was heated with 40% NaOH (40 mL) and EtOH (200 mL). The unreacled ester was extracted with Et20 and the aqueous solution was acidified to obtain crude 2, which after distillation afforded 24 g ol 2(52%), bp t60-185°C/ 2mm. 

Diazoacetic esters are potentially explosive and therefore must be handled with caution. They are also toxic and prone to cause development of specific sensitivity. A well-ventilated hood should be used for the entire procedure. 

Alkyl diethylphosphononuoroacetates have been used extensively in ol fi-nanon procedures [69], principally forming the ffJ-a-fluoro-a.P-unsaturated esters with very high stereoselectivity [70] (equation 61) (Table 22). Preparation of the ethyl diethylphosphonofluoroacetate from ethyl fluoroacetate has obviated the necessity to prepare ethyl bromofluoroacetate from bromine fluoride and ethyl diazoacetate [71],... 

In addition to the reactions descubed m the prcpaiation diazoacetic ester unites with misaturatecl acids andfoims cyclic compounds. Fumaric cstei, for example, combines in the following way —... 

In this review an attempt is made to discuss all the important interactions of highly reactive divalent carbon derivatives (carbenes, methylenes) and heterocyclic compounds and the accompanying molecular rearrangements. The most widely studied reactions have been those of dihalocarbenes, particularly dichlorocarbene, and the a-ketocarbenes obtained by photolytic or copper-catalyzed decomposition of diazo compounds such as diazoacetic ester or diazoacetone. The reactions of diazomethane with heterocyclic compounds have already been reviewed in this series. ... 

The copper-catalyzed decomposition of diazoacetic ester in the presence of pyrrole was first described in 1899 and later investigated in more detail by Nenitzescu and Solomonica. Ethyl pyrrole-2-acetate (13), the normal product of electrophilic substitution, was obtained in 50% yield and was degraded to 2-methylpyrrole. Similarly iV -methylpyrrole with two moles of diazoacetic ester gave, after hydrolysis, the 2,5-diacetic acid (14) while 2,3,5-trimethylpyrrole gave, after degradation, 2,3,4,5-tetramethylpyrrole by substitution of ethoxycarbonylcarbene at the less favored )3-position. Nenitzescu and Solomonica also successfully treated pyrroles with phenyl-... 

Jackson and Manske described the decomposition of diazoacetic ester with indoles to give, after hydrolysis, the 3-acetic acid and some 1,3-diacetic acid no product of 2-substitution was found (see also ref. 49). Diazoacetone and diazopyruvic ester similarly gave the 3-sub-stituted indoles.Badger et al. have also examined the reaction of iV -methylindole, as well as of indole, with diazoacetic ester. Again only the 3-substituted product resulted and no evidence was obtained for addition. 

What evidence is there for the individual reaction steps The add-base reaction (Eq, 2) has the characteristics of a Broensted equilibrium, as has been shown in the case of diazomethane-benzoic acid (in toluene). Further evidence for this is provided by the reactions of diazoacetic ester and diazo ketones. The occurrence of free, mobile diazonium cations is also supported by the fact that solutions of diazomethane in methanol show greater conductivity than solutions of pure solvent. ... 

A solution containing 167 grams of stabilized styrene and 183 grams of ethyl diazoacetate is cooled to 0°C and dropped into 83.5 grams of styrene with stirring, in a dry nitrogen atmosphere, at 125° to 135°C, This produced the ester ethyl 2-phenylcyclopropanecar-boxylate. 

The BF3 Et20-catalyzed aziridination of compounds 47 (Scheme 3.15) with a diazo ester derived from (R)-pantolacetone gave aziridine-2-carboxylates 48 [59]. The reaction exhibited both high cis selectivity (>95 <5) and excellent diastereose-lectivity. Treatment of a-amino nitrile 49 (Scheme 3.16) with ethyl diazoacetate in the presence of 0.5 equivalent of SnCl4 afforded aziridines 50 and 51 in 39% yield in a ratio of 75 25 [60]. 

Ethyl benzoylacetate has been prepared by the condensation (by means of sodium ethylate) of ethyl acetate with ethyl benzoate,1 acetophenone with ethyl carbonate,2 and acetophenone with ethyl oxalate, with subsequent heating 3 by treatment of ethyl phenylpropiolate4 or a-bromocinnamic acid 5 with concentrated sulfuric acid, and of ethyl diazoacetate with benzalde-hyde 6 by the condensation of benzene with the monoethyl ester of malonyl monoacid chloride and aluminum chloride,7 of benzoyl chloride with the product of the reaction of magnesium and ethyl chloroacetate in ether,8 of alcohol on benzoylacetimino ethyl... 

P-Keto esters have been prepared in moderate to high yields by treatment of aldehydes with diethyl diazoacetate in the presence of a catalytic amount of a Lewis acid such as SnCL, BF3, or GeCL. The reaction was successful for both aliphatic and aromatic aldehydes, but the former react more rapidly than the latter, and the difference is great enough to allow selective reactivity. In a similar process, aldehydes react with certain carbanions stabilized by boron, in the presence of (F3CC0)20 or NCS, to give ketones. 

Carbenes and substituted carbenes add to double bonds to give cyclopropane derivatives ([1 -f 2]-cycloaddition). Many derivatives of carbene (e.g., PhCH, ROCH) ° and Me2C=C, and C(CN)2, have been added to double bonds, but the reaction is most often performed with CH2 itself, with halo and dihalocarbenes, " and with carbalkoxycarbenes (generated from diazoacetic esters). Alkylcarbenes (HCR) have been added to alkenes, but more often these rearrange to give alkenes (p. 252). The carbene can be generated in any of the ways normally used (p. 249). However, most reactions in which a cyclopropane is formed by treatment of an alkene with a carbene precursor do not actually involve free carbene... 

The diazo transfer reaction between p-toluenesulfonyl azide and active methylene compounds is a useful synthetic method for the preparation of a-diazo carbonyl compounds. However, the reaction of di-tert-butyl malonate and p-toluenesulfonyl azide to form di-tert-butyl diazomalonate proceeded to the extent of only 47% after 4 weeks with the usual procedure." The present procedure, which utilizes a two-phase medium and methyltri-n-octylammonium chloride (Aliquat 336) as phase-transfer catalyst, effects this same diazo transfer in 2 hours and has the additional advantage of avoiding the use of anhydrous solvents. This procedure has been employed for the preparation of diazoacetoacetates, diazoacetates, and diazomalonates (Table I). Ethyl and ten-butyl acetoacetate are converted to the corresponding a-diazoacetoacetates with saturated sodium carbonate as the aqueous phase. When aqueous sodium hydroxide is used with the acetoace-tates, the initially formed a-diazoacetoacetates undergo deacylation to the diazoacetates. Methyl esters are not suitable substrates, since they are too easily saponified under these conditions. 

Although the hazardous properties of di-tert-butyl diazomalo-nate are not known with certainty, it is reasonable to assume that they are similar to those of diazoacetic esters, which are considered to be moderate explosion hazards when heated. Contact with rough or metallic surfaces should be avoided. The submitter has routinely distilled 10-g. quantities of di-ferf-butyl diazomalonate under argon with no sign of decomposition. 

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