Ethyl acetoacetate acidity

Ethoxylated Dodecanol Ethoxylated Dodecyl Alcohol Ethoxylated Myristyl Alcohol Ethoxylated Nonylphenol Ethoxylated Pentadecanol Ethoxylated Pentadecyl Alcohol Ethoxylated Tetradecanol Ethoxylated Tetradecyl Alcohol Ethoxylated Tridecanol Ethoxylated Tridecyl Alcohol Ethoxytriethylene Glycol Ethoxy Triglycol Ethyl Acetate Ethylacetic Acid Ethyl Acetoacetate Ethyl Acrylate Ethyl Alcohol Ethyl Aldehyde Ethylaluminum Dichloride Ediylaluminum Sesquichloride Ethylamine Ethylbenzene Ethyl Butanoate Ethyl Butanol 2-Ethyl-1 -Butanol 2-Ethylbutyl Alcohol Ethyl Butyrate... 

Problem 23.10 when ethyl acetoacetate (CH3COCH2CO2CH2CH3) is treated with one equivalent of CHsMgBr, a gas is evolved from the reaction mixture, and after adding aqueous acid, ethyl acetoacetate is recovered in high yield. Identify the gas formed and explain why the starting material was recovered in this reaction. 

Ethoxylated Tridecanol Ethoxylated Tridecyl Alcohol Ethoxytriethylene Glycol Ethoxy Triglycol Ethyl Acetate Ethylacetic Acid Ethyl Acetoacetate Ethyl Acrylate Ethyl Alcohol Ethyl Aldehyde Ethylaluminum Dichloride... 

Compound Name Ethoxylated Pentadecanol Ethoxylated Tetradecanol Ethoxylated Tetradecanol Ethoxylated Tridecanol Ethoxylated Tridecanol Ethoxy Triglycol Ethoxy Triglycol Ethyl Acetate N-Butyric Acid Ethyl Acetoacetate Ethyl Acrylate Ethyl Alcohol Acetaldehyde Ethylaluminum Dichloride Ethylaluminum Sesquichloride Ethylaniine Ethylbenzene Ethyl Butyrate Ethyl Butanol Ethyl Butanol Ethyl Butanol Ethyl Butyrate Ethylhexaldehyde N-Propyl Alcohol Diethyl Carbonate Ethyl Chloracetate Ethyl Chloride Ethyl Chloroacetate Ethyl Chloroformate Ethyl Chloroacetate Ethyl Chloroacetate Ethyl Phosphorodi-chloridate Ethyldichlorosilane Ethylene Ethylene Glycol Diacetate... 

Hydrolysis. Ethyl acetoacetate when treated w ith cold dilute sodium hydroxide solution gives the sodium salt of acetoacetic acid. This acid is unstable, and readily breaks down into acetone and carbon dioxide it is of considerable... 

In brief, suitable hydrolysis of ethyl acetoacetate derivatives will give mono-or di-alkyl substituted acetones or acetic acids. Tri-substituted acetones or acetic acids cannot be obtained moreover, the di-substituted acetones must... 

Mix 6 2 ml. (6 4 g.) of pure ethyl acetoacetate and 5 ml. of pure phenylhydrazine in an evaporating-basin of about 75 ml. capacity, add 0 5 ml. of acetic acid and then heat the mixture on a briskly boiling water-bath (preferably in a fume-cupboard) for I hour, occasionally stirring the mixture with a short glass rod. Then allow the heavy yellow syrup to cool somewhat, add 30-40 ml. of ether, and stir the mixture vigorously the syrup may now dissolve and the solution shortly afterwards deposit the crystalline pyrazolone, or at lower temperatures the syrup may solidify directly. Note. If the laboratory has been inoculated by previous preparations, the syrup may solidify whilst still on the water-bath in this case the solid product when cold must be chipped out of the basin, and ground in a mortar with the ether.) Now filter the product at the pump, and wash the solid material thoroughly with ether. Recrystallise the product from a small quantity of a mixture of equal volumes of water and ethanol. The methyl-phenyl-pyrazolone is obtained... 

It follows therefore that ethyl malonate can be used (just as ethyl aceto- acetate) to prepare any mono or di-substituted acetic acid the limitations are identical, namely the substituents must necessarily be alkyl groups (or aryl-alkyl groups such as CjHjCHj), and tri-substituted acetic acids cannot be prepared. Ethyl malonate undergoes no reaction equivalent to the ketonic hydrolysis of ethyl acetoacetate, and the concentration of the alkali used for the hydrolysis is therefore not important. 

In the present preparation, ethyl acetoacetate is treated with sufficient nitrous acid to convert half into the a-nitroso (or a-oximino) ester, which is reduced by zinc and acetic acid to the a-amino ester (I). The latter then condenses with... 

Required Ethyl acetoacetate, 20 g. sodium nitrite, 5 4 g. zinc dust, 11 g. glacial acetic acid, 60 ml. 

Fit a three necked 250 ml. flask with a central rubber-sleeved or mercury-sealed stirrer, c/. Fig. 23(c), p. 45, where only two necks are shown, and with a thermometer the bulb of which reaches as near the bottom of the flask as the stirrer allows the third neck will carry at first a dropping-funnel and later a reflux condenser. Place 20 g. (19-5 ml.) of ethyl acetoacetate and 45 ml. of glacial acetic acid in the flask and by ice-water cooling adjust the temperature of the stirred mixture to 5 -7° maintain this temperature whilst adding a solution of 5 4 g. of sodium nitrite in 8 ml. of water slowly from the dropping-funnel during 15 minutes. Continue the stirring for 20-30 minutes, and then... 

This reaction consists of the condensation of two molecular equivalents of a 1,3 diketone (or a J3-keto-ester) with one equivalent of an aldehyde and one of ammonia. Thus the interaction of ethyl acetoacetate and acetaldehyde and ammonia affords the 1,4-dihy dro-pyridine derivative (1), which when boiled with dilute nitric acid readily undergoes dehydrogenation and aromatisation" to gb e the diethyl ester of collidine (or 2,4,6-trimethyl-pyridine-3,5 dicarboxylic acid (II)). For the initial condensation the solid aldehyde-ammonia can conveniently be used in place of the separate reagents. 

Gently warm a mixture of 32 g. (32 ml.) of ethyl acetoacetate and 10 g. of aldehyde-ammonia in a 400 ml. beaker by direct heating on a gauze, stirring the mixture carefully with a thermometer. As soon as the reaction starts, remove the heating, and replace it when the reaction slackens, but do not allow the temperature of the mixture to exceed 100-no the reaction is rapidly completed. Add to the mixture about twice its volume of 2A -hydrochloric acid, and stir the mass until the deposit either becomes solid or forms a thick paste, according to the quality of the aldehyde-ammonia employed. Decant the aqueous acid layer, repeat the extraction of the deposit with more acid, and again decant the acid, or filter off the deposit if it is solid. Transfer the deposit to a conical flask and recrystallise it twice from ethanol (or methylated spirit) diluted with an equal volume of water. The i,4-dihydro-collidine-3,5-dicarboxylic diethyl ester (I) is obtained as colourless crystals, m.p. 130-131°. Yield 12 5 g,... 

For the preparation of 4-substituted coumarins, a phenol may be condensed with ethyl acetoacetate under the influence of sulphuric acid. Thus resorcinol (II) readily undergoes this condensation (which is represented diagrammatically above) to give 7-hydroxy-4-methyl-coumarin (III). Note that the coumarins, like all 2 pyrones, are systematically lactones. 

Ethyl acetoacetate may be prepared by the action of sodium upon dry ethyl acetate and decomposition of the resulting sodio compound with dilute acetic acid. Most samples of ethyl acetate contain some ethyl alcohol and it is usually assumed that sodium ethoxidc is the condensing agent ... 

Ethyl acetoacetate decomposes slightly (with the formation of dehydracetio acid C,H,0,) when distilled at atmospheric pressure. The extent of decomposition is reduced if the distillation is conducted rapidly. The b.p, is 180°/760 mm. and a 6° fraction should be collected. Normal pressure distillation is not recommended if a pure product is desired. 

This is an alternative experiment to the actual preparation of the ester and will give the student practice in conducting a distillation under diminished pressure. Commercial ethyl acetoacetate generally contains inter alia some ethyl acetate and acetic acid these are removed in the following procedure. 

Resorcinol condenses similarly with ethyl acetoacetate in the presence of concentrated sulphuric acid to give 4-methyl-7-hydroxycoumarln. 

A simplified procedure is possible by using polyphosphoric acid as the condensing agent. Add 160 g. of polyphosphoric acid to a solution of 11 g. of resorcinol in 13 g. of ethyl acetoacetate. Stir the mixture and heat at 75-80° for 20 minutes, and then pour into ice-water. Collect the pale yellow solid by suction filtration, wash with a little cold water, and dry at 60°. The yield of crude 4-methyl-7-hydroxycoumarin, m.p. 178-181°, is 17 g. Recrystalbsation from dilute ethanol yields the pure, colourless compound, m.p. 185°. 

The properties of diethyl malonate that make the malonic ester synthesis a useful procedure are the same as those responsible for the synthetic value of ethyl acetoacetate The hydrogens at C 2 of diethyl malonate are relatively acidic and one is readily removed on treatment with sodium ethoxide... 

Acetic acid, fp 16.635°C ((1), bp 117.87°C at 101.3 kPa (2), is a clear, colorless Hquid. Water is the chief impurity in acetic acid although other materials such as acetaldehyde, acetic anhydride, formic acid, biacetyl, methyl acetate, ethyl acetoacetate, iron, and mercury are also sometimes found. Water significantly lowers the freezing point of glacial acetic acid as do acetic anhydride and methyl acetate (3). The presence of acetaldehyde [75-07-0] or formic acid [64-18-6] is commonly revealed by permanganate tests biacetyl [431-03-8] and iron are indicated by color. Ethyl acetoacetate [141-97-9] may cause slight color in acetic acid and is often mistaken for formic acid because it reduces mercuric chloride to calomel. Traces of mercury provoke catastrophic corrosion of aluminum metal, often employed in shipping the acid. 

Conra.d-Limpa.ch-KnorrSynthesis. When a P-keto ester is the carbonyl component of these pathways, two products are possible, and the regiochemistry can be optimized. Aniline reacts with ethyl acetoacetate below 100°C to form 3-anilinocrotonate (14), which is converted to 4-hydroxy-2-methylquinoline [607-67-0] by placing it in a preheated environment at 250°C. If the initial reaction takes place at 160°C, acetoacetanilide (15) forms and can be cyclized with concentrated sulfuric acid to 2-hydroxy-4-methylquinoline [607-66-9] (49). This example of kinetic vs thermodynamic control has been employed in the synthesis of many quinoline derivatives. They are useful as intermediates for the synthesis of chemotherapeutic agents (see Chemotherapeuticsanticancer). 

Coumarin can also be formed by the reaction of phenol with diketene (40). Similarly, diphenols can react with hydroxycarboxyUc acids or beta-ketoesters to give hydroxycoumaria derivatives. The reaction of resorciaol with malic acid produces umbeUiferone (7-hydroxycoumaria) and its reaction with ethyl acetoacetate gives beta-methylumbeUiferone (7-hydroxy-4-methylcoumaria). 

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