Ethanol ethylamine

Polychloroprene 1-2 h aniline, ethanol, ethylamine, kerosene, sulphuric acid (cone.)... 

Schatzmann, in 1891, tried to prepare 2-thiazolines by hydrogenation of thiazoles and by the action of sodium and ethanol on 2,4-dimethyl-thiazole, 2-methylthiazole, and 2-methyl-4-phenylthiazole (476). None of these substrates was reduced to thiazoline the second gave no reaction and the first underwent ring cleavage, leading to a mixture of n-propylmercaptan and ethylamine (Scheme 90). Three years later the same... 

Ethylamines. Mono-, di-, and triethylamines, produced by catalytic reaction of ethanol with ammonia (330), are a significant outlet for ethanol. The vapor-phase continuous process takes place at 1.38 MPa (13.6 atm) and 150—220°C over a nickel catalyst supported on alumina, siUca, or sihca—alumina. In this reductive amination under a hydrogen atmosphere, the ratio of the mono-, di-, and triethylamine product can be controlled by recycling the unwanted products. Other catalysts used include phosphoric acid and derivatives, copper and iron chlorides, sulfates, and oxides in the presence of acids or alkaline salts (331). Piperidine can be ethylated with ethanol in the presence of Raney nickel catalyst at 200°C and 10.3 MPa (102 atm), to give W-ethylpiperidine [766-09-6] (332). 

Special reactions of hydrazides and azides are illustrated by the conversion of the hydrazide (205) into the azide (206) by nitrous acid (60JOC1950) and thence into the urethane (207) by ethanol (64FES(19)105Q) the conversion of the same azide (206) into the N-alkylamide (208) by ethylamine the formation of the hydrazone (209) from acetaldehyde and the hydrazide (205) and the IV-acylation of the hydrazide (205) to give, for example, the formylhydrazide (210) (65FES(20)259). It is evident that there is an isocyanate intermediate between (206) and (207) such compounds have been isolated sometimes, e.g. (211). Several of the above reactions are involved in some Curtius degradations. 

Subsequently, the reaction mixture is stirred at a temperature of 0° to 5°C for 20 hours, after which 50 ml of absolute ethanol are added. Then the ethylamine is distilled off at low pressure. To the remaining solution 50 ml of ether and 50 ml of water are added. The water layer Is separated and extracted a few times with ether. The collected ether extracts are added to the ethereal layer, after which this ethereal solution is washed with a 2N hydrochloric acid solution, subsequently with a saturated sodium bicarbonate solution, and then with water. The ethereal solution is then dried on sodium sulfate and finally evaporated to dryness. 

Ethanol s many uses can be conveniently divided into solvent and chemical uses. As a solvent, ethanol dissolves many organic-based materials such as fats, oils, and hydrocarbons. As a chemical intermediate, ethanol is a precursor for acetaldehyde, acetic acid, and diethyl ether, and it is used in the manufacture of glycol ethyl ethers, ethylamines, and many ethyl esters. 

A. fi(-)-a-(l-Naphthyl)ethylamine. A mixture of 58.44 g. (0.20 mole) of (-)-2,3 4,6-di-0-isopropylidene-2-keto-L-gulonic acid hydrate [(-)-DAG] (Note 1) and 1.7 1. of acetone (Note 2) is placed in a 3-1. Erlenmeyer flask. A boiling chip is added, and the mixture is heated to a gentle boil. To the resulting hot solution is added cautiously but rapidly, over a 1 minute period, 34.24 g. (0.20 mole) of racemic y.- 1 -naphthyl)et hylamine (Note 3) in 100 ml. of acetone. The mixture is allowed to stand at room temperature for approximately 4 hours. The (-)-amine (-)-DAG salt is filtered with suction, washed with 100 ml. of acetone, and dried in a vacuum oven at 60° to constant weight. The yield of the crude (-)-amine (-)DAG salt is 73-76 g., m.p. 205-207° (decomp.) (Note 4), [a]p —14.2° (c 1.01%, methanol). For crystallization, the crude salt and 4.2 1. of ethanol (Note 5) are placed in a 5-1. round-bottomed flask fitted with a reflux condenser and a mechanical stirrer. The mixture is stirred and heated at reflux... 

Results. In the past two years we have undertaken a high pressure examination of the ion-molecule reactions occurring in a series of polar molecules—namely, methylamine, methanol, ethylamine, and ethanol (3). In all cases, the major secondary ion is the (parent +1) ion and in the first two cases, it is the only secondary ion. All hydrogenic primary ions undergo the general reaction,... 

It is difTicult to choose between groups when using the Hass table the substance can belong to group 4 (ethylamine) or 7 (ethylene glycol) or even 8 (ethanol). 

Ethylamine(s), 2 537t ACGIH TLV, 2 548t derivation from ethanol, 10 556 physical and chemical properties of, 2 540t... 

The most successful modifier is cinchonidine and its enantiomer cinchonine, but some work in expanding the repertoire of substrate/modifier/catalyst combinations has been reported (S)-(-)-l-(l-naphthyl)ethylamine or (//)-1 -(I -naphth T)eth Tamine for Pt/alumina [108,231], derivatives of cinchona alkaloid such as 10,11-dihydrocinchonidine [36,71], 2-phenyl-9-deoxy-10, 11-dihydrocinchonidine [55], and O-methyl-cinchonidine for Pt/alumina [133], ephedrine for Pd/alumina [107], (-)-dihydroapovincaminic acid ethyl ester (-)-DHVIN for Pd/TiOz [122], (-)-dihydrovinpocetine for Pt/alumina [42], chiral amines such as 1 -(1 -naphtln I)-2-(I -pyrro 1 idiny 1) ethanol, l-(9-anthracenyl)-2-(l-pyrrolidinyl)ethanol, l-(9-triptycenyl)-2-(l-pyrrol idi nyl)cthanol, (Z )-2-(l-pyrrolidinyl)-l-(l-naphthyl)ethanol for Pt/alumina [37,116], D- and L-histidine and methyl esters of d- and L-tryptophan for Pt/alumina [35], morphine alkaloids [113],... 

Another large class of chemicals produced starting from ethanol are ethyl-amines. When heated to 150-220 °C over a silica- or alumina-supported nickel catalyst, ethanol and ammonia react to produce ethylamine. Further reaction leads to diethylamine and triethylamine. The ethylamines find use in the synthesis of pharmaceuticals, agricultural chemicals, and surfactants. 

The reactions of 2-(3,4-dimethoxyphenyl)ethylamine hydrochlorides with the sodium derivative of diethoxycarbonylglutaconate (8, R = H) in refluxing ethanol afforded the corresponding aminomethylenemalonates (357) in 84-885 yields (56JOC336). 

The CSAs that have been used most widely are 2,2,2-trifluoro-l-phenylethanol (TFPE, la), 2,2,2-trifluoro-l-(l-naphthyl)ethanol (TFNE, lb), 2,2,2-trifluoro-l-(9-anthryl)ethanol (TFAE, Ic), 1-phenylethylamine (PEA, 2a), and l-(l-naphthyl)ethylamine (NEA, 2b). Both enantiomers of TFPE, TFAE (9), PEA, and NEA are commercially available. The fluoroalcohols are relatively acidic and interact strongly with solutes having one or more basic sites (Sect. IV-B). Amines 2 have been used most often as CSAs for organic acids or other acidic solutes (Sect. IV-C). A number of analogs of TFAE have been studied (Sect. III-C). 

Carvedilol (S) -indol ine-carboxylic acid and (R)-l-(a-naph-thyl) ethylamine -Hexane/dichloromethane/ ethanol (50 35 15, v/v/v) + 0.25% (v/v) trifluoroacetic acid (TEA) 198... 

There is also a relationship between p a-values of ethanol, phenol and acetic acid on the one hand, and ethylamine, aniline and acetamide on the other (Liler, 1971c, p. 108), which may be presented as a linear free energy relationship (Figure 6) by regarding Et, Ph and CH3 CO as substituents (R). This excellent relationship leaves no doubt that the acidic group in the R—NH3 series remains unchanged, i.e., that acetylammonium ion is formed in the protonation of acetamide in aqueous acid (half-protonation in ca. 19% sulphuric acid). 

The ether extract contains benzenesulfonyl diethylamine, some dibenzenesulfonyl ethylamine and the excess of benzenesulfonyl chloride. Evaporate the ether, warm the residual oil for half an hour, with 10 ml of 6 M NaOH with enough ethanol to keep the oil in solution (dissolved). Cool with an ice and CaCl mixture, seed by rubbing or scratching a glass rod in the vessel, and with stirring, dilute slowly with 100 ml of NaCl solution (30 g of NaCl per liter). Allow to stand for 12-16 hours. Remove the benzenesulfonyl diethylamine by filtration and wash with cold, saturated (this is not the same as above) NaCl solution. Add the filtrate to the NaOH solution. 

Similar results were achieved when benzene was reduced with alkali metals in anhydrous methylamine at temperatures of 26-100°. Best yields of cyclohexene (up to 77.4%) were obtained with lithium at 85° [396]. Ethylamine [397] and especially ethylenediamine are even better solvents [398]. Benzene was reduced to cyclohexene and a small amount of cyclohexane [397, 398] ethylbenzene treated with lithium in ethylamine at —78° gave 75% of 1-ethyl-cyclohexene whereas at 17° a mixture of 45% of 1-ethylcyclohexene and 55% of ethylcyclohexane was obtained [397], Xylenes m- and p-) yielded non-conjugated 2,5-dihydro derivatives, l,3-dimethyl-3,6-cyclohexadiene and 1,4-dimethyl-1,4-cyclohexadiene, respectively, on reduction with sodium in liquid ammonia in the presence of ethanol (in poor yields) [399]. Reduction of diphenyl with sodium or calcium in liquid ammonia at —70° afforded mainly 1-phenylcyclohexene [400] whereas with sodium in ammonia at 120-125° mainly phenylcyclohexane [393] was formed. 

Active methylene nitriles condense with o-substituted aryl and heteroaryl azides in a two-step process to give tricyclic triazolopyrimidines without isolation of the triazole intermediates <85BSB441, 87BSB587). 5-Azido-4-formyltriazoles (758) condense with dimethyl 3-oxopentanedioate and tri-ethylamine in ethanol to give 5-(triazol-l-yl)-4-formyltriazoles (759), which undergo cyclization to... 

In a study involving 3-methylfervenulin 50 (R = Me) <1996JHC949>, shown in Scheme 4, it was found that reaction with methanolic methylamine or ethylamine at room temperature gave the imidazo[4,5-i ]-l,2,4-triazines 52a and 52b, respectively. This transformation is believed to proceed via the intermediate l,2,4-triazin-6-yl urea derivatives 51. The same investigation showed that the reaction of a range of 3-alkylfervenulins 50 with ethanolic sodium hydroxide gave the 3-alkyl imidazo[4,5-i ]-l,2,4-triazines 53. 

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