Methyl ethyl oxalate

Methyl, ethyl, n-propyl, isopropyl, n-hutyl, benzyl, cyclohexyl esters of formic, acetic, oxalic, succinic, tartaric, citric, benzoic, salicylic (and other substituted benzoic acids), phthalic and cinnamic acids phenyl esters of acetic, benzoic and salicylic acids. 

Dissolve 0 2 g. of methyl oxalate in 10 ml. of water, add without delay 1 ml. of ammonia (d, o 88o) and shake a fine white precipitate of the insoluble oxamide is produced. A precipitate of oxamide is similarly produced when 2-3 drops of ammonia are added directly to 0 5 ml. of ethyl oxalate. 

Ethyl oxalate is the only liquid ester which gives this rapid separation of the amide, which is therefore characteristic. Methyl and ethyl formate react rapidly with ammonia, but the soluble formamide does not separate methyl succinate gives crystalline succinamide after about I hour s standing, other esters only after a much longer time. The solid esters, other than methyl oxalate, are either soluble in water and remain so when treated with ammonia, or alternatively are insoluble in water and hence clearly not methyl oxalate. 

NOTE. Many esters reduce Fehling s solution on warming. This reduction occurs rapidly with the alkyl esters of many aliphatic acids, but scarcely at all with similar esters of aromatic acids (f.g., ethyl oxalate reduces, but ethyl benzoate does not). Note also that this is a property of the ester itself thus both methyl and ethyl oxalate reduce Fehling s solution very rapidly, whereas neither oxalic acid, nor sodium oxalate, nor a mixture of the alcohol and oxalic acid (or sodium oxalate), reduces the solution. 

Of the common esters, methyl oxalate (solid, m.p. 54°) and ethyl oxalate (liquid) give amides almost immediately upon shaking with concentrated ammonia solution. The resulting oxamide, m.p. 417°, is valueless as a derivative. The esters may, however, be easily hydrolysed and identified as above. 

Successful results have been obtained (Renfrew and Chaney, 1946) with ethyl formate methyl, ethyl, n-propyl, iso-propyl, n-butyl, iso-butyl, sec.-butyl and iso-amyl acetat ethyleneglycol diacetate ethyl monochloro- and trichloro-acetates methyl, n-propyl, n-octyl and n-dodecyl propionates ethyl butyrate n-butyl and n-amyl valerates ethyl laurate ethyl lactate ethyl acetoacetate diethyl carbonate dimethyl and diethyl oxalates diethyl malonate diethyl adipate di-n-butyl tartrate ethyl phenylacetate methyl and ethyl benzoates methyl and ethyl salicylates diethyl and di-n-butyl phthalates. The method fails for vinyl acetate, ieri.-butyl acetate, n-octadecyl propionate, ethyl and >i-butyl stearate, phenyl, benzyl- and guaicol-acetate, methyl and ethyl cinnamate, diethyl sulphate and ethyl p-aminobenzoate. 

Alcohols, esters (but not ethyl benzoate, ethyl malonate or ethyl oxalate), aldehydes, methyl ketones and cyclic ketones containing less than nine carbon atoms as well as ethers containing less than seven carbon atoms are soluble in 85 p>er cent, phosphoric acid. 

Cobalt salts are used as activators for catalysts, fuel cells (qv), and batteries. Thermal decomposition of cobalt oxalate is used in the production of cobalt powder. Cobalt compounds have been used as selective absorbers for oxygen, in electrostatographic toners, as fluoridating agents, and in molecular sieves. Cobalt ethyUiexanoate and cobalt naphthenate are used as accelerators with methyl ethyl ketone peroxide for the room temperature cure of polyester resins. 

Both 2- and 3-methyl groups in pyrido[2,3-Z ]pyrazines are acylated by ethyl oxalate (71TH21500). They give (preferentially 3-) styryl derivatives with aromatic aldehydes and oximes with pentyl nitrite. 

The reactivity of the methylene group adjacent to the lactam group affords the possibility of a Claisen condensation. Thus, treatment of 2-pyrrolidone or 2-piperidone with ethyl oxalate leads to the J -pyrroline-carboxylic (70) and, d -piperideine-2-carboxylic acids (71), respectively. N-methyl lactams furnish N-methyl derivatives (72,73) (Scheme 3). 

A thioamide of isonicotinic acid has also shown tuberculostatic activity in the clinic. The additional substitution on the pyridine ring precludes its preparation from simple starting materials. Reaction of ethyl methyl ketone with ethyl oxalate leads to the ester-diketone, 12 (shown as its enol). Condensation of this with cyanoacetamide gives the substituted pyridone, 13, which contains both the ethyl and carboxyl groups in the desired position. The nitrile group is then excised by means of decarboxylative hydrolysis. Treatment of the pyridone (14) with phosphorus oxychloride converts that compound (after exposure to ethanol to take the acid chloride to the ester) to the chloro-pyridine, 15. The halogen is then removed by catalytic reduction (16). The ester at the 4 position is converted to the desired functionality by successive conversion to the amide (17), dehydration to the nitrile (18), and finally addition of hydrogen sulfide. There is thus obtained ethionamide (19)... 

Menthone has been prepared synthetically by Kotz and Hesse from methyl hexanone. This body was condensed with ethyl oxalate by adding... 

Methyl ethyl ketone Ethyl oxalate Hydrogen chloride Ammonia Cyanacetamid Ethanol ... 

Ethyl Propianyl-Pyruvate 36 grams of methyl ethyl ketone and 73 grams of ethyl oxalate are condensed in the presence of sodium ethylate, the reaction mixture being refluxed in an alcoholic medium. 28 grams of the desired product having a boiling point of 100° to 105°C/6 mm are obtained. 

A) Ethyl Butyryl-Pyruvate 146 grams of ethyl oxalate are condensed with 86 grams of methyl-(n)-propyl-ketOne in the presence of sodium ethylate prepared from 25 grams of sodium. 135 grams of product, having a boiling point of 1l3°C/6 mm, are obtained. 

N-Nitroso-N-methyl-N -nitroguanidine, diazomethane from, 41, 10 Nitrosomethylurethane, warning because a carcinogen, 43, 86 o-Nitrotoluene, condensation with ethyl oxalate, 43,40... 

Dimethyl peroxide Diethyl peroxide Di-t-butyl-di-peroxyphthalate Difuroyl peroxide Dibenzoyl peroxide Dimeric ethylidene peroxide Dimeric acetone peroxide Dimeric cyclohexanone peroxide Diozonide of phorone Dimethyl ketone peroxide Ethyl hydroperoxide Ethylene ozonide Hydroxymethyl methyl peroxide Hydroxymethyl hydroperoxide 1-Hydroxyethyl ethyl peroxide 1 -Hydroperoxy-1 -acetoxycyclodecan-6-one Isopropyl percarbonate Isopropyl hydroperoxide Methyl ethyl ketone peroxide Methyl hydroperoxide Methyl ethyl peroxide Monoperoxy succinic acid Nonanoyl peroxide (75% hydrocarbon solution) 1-Naphthoyl peroxide Oxalic acid ester of t-butyl hydroperoxide Ozonide of maleic anhydride Phenylhydrazone hydroperoxide Polymeric butadiene peroxide Polymeric isoprene peroxide Polymeric dimethylbutadiene peroxide Polymeric peroxides of methacrylic acid esters and styrene... 

Methylene bromide, 112 Methyl ethyl ketone, 23 a-Methyl d-glucoside, 112 Methyl Oxalate, 70 Myristyl alcohol, 64... 

Following are the percentage yields obtained in the preparation of other esters ethyl maleate, 73 ethyl salicylate, 70 ethyl oxalate, 80 ethyl benzoate, 92 methyl benzoate, 87. In the preparation of ethyl maleate troublesome emulsions were encountered in working up the product. Occasionally this hap-... 

However, the presence of a negative group is not always necessary 3-phenyl-5-methyl oxadiazole reacts with benzaldehyde in the presence of zinc chloride to give j8(phenyl-3-oxadiazolyl)styrene. With ethyl oxalate (phenyl-3-oxadiazolyl) pyruvate is formed in a Claisen condensation. 

The tetrahydropyridopyrimidine 394 was obtained via condensation of 5-acetyl-4-arylamino-6-methyl-2-styrylpyr-imidine with benzaldehyde <1997PJC1232>. The 5,8-dihydropyrido[2,3 Pyrimidine derivatives 395 could be obtained from condensing 5-acetyW-amino-2,6-disubstituted pyrimidines with ethyl oxalate in the presence of alkoxide by-products of Friedlander self-condensation of 395 were also obtained <2002RCB1875>. 

In order to activate the 21 position to halogenation, it is hrst converted to an oxalate. Condensation of the triketone with ethyl oxalate in the presence of alkoxide proceeds preferentially at the 21 position to give (12-2) due to the well-known enhanced reactivity of methyl ketones. Reaction of the crude sodium enolate with bromine leads to the dibromide (12-3), the oxalate moiety being cleaved under the reaction conditions. The Favorskii rearrangement is then used to, in effect, oxidize the 17 position so as to provide a site for the future hydroxyl group. Thus, treatment of (12-3) with an excess of sodium methoxide hrst provides an anion at the 17 position (12-4). This then cyclizes to the transient cyclopropanone (12-5)... 

Methyl-5-oxo-l,5-dihydro-8-carbamoyl-l,2,4-triazolo[4,3-c]pyrimidines 577 and 578 were prepared by the cyclization of 576 with acetic anhydride and ethyl oxalate, respectively (89PHA604).The 4-methyl-l,2-dihydropyra-zolo[3,4-d]pyrimidine-3,6-dione 579 also was obtained in the latter case, as a consequence of breaking the amide bond and releasing the amine moiety. Coupling ethyl dithioacetate and 5-chloro-4-hydrazinopyrimidine (580) afforded the triazolo[4,3-c]pyrimidine 581 (89H239) (Scheme 114). 

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