Ethyl, amine nitrite

Grouping Acetone Ethane Ethyl-acetate Acetylene Ethyl amine Ethylene Acetaldehyde Ethyl glycol Crude oil Ethyl-ether Carbon disulphide Ethyl Nitrite... 

In conclusion, we propose a specific research program for deaminations in aqueous systems based on ideas mentioned in this section, namely to investigate (a) deamination kinetics and products of a series of simple aliphatic amines in water with sodium nitrite and perchloric acid at various acidities, (b) decompositions of diazenolates of the same amines in water and (c) decompositions of a standard type of N-nitroso amides, again of the same amines and all in the same aprotic solvent. The reaction conditions should be as similar as possible in the experiments of all three series. The series of amines should include methyl-, ethyl-, 1-methylethyl-, 1-methylpropyl-, and ( cr butyl)amine and [l- H]ethylamine, but not amines with longer aliphatic chains, as the very informative work of Southam and Whiting (1982) demonstrated clearly that, in deaminations of such amines, many mechanistically complex products are formed. In addition, micellar effects increase the complexity of reactions with such amines (see Sect. 7.3). It is obvious from the series of amines that we have proposed that this program is based on the work of Brosch and Kirmse (1991), Hovinen and Fishbein (1992), Hovinen et al. (1992), Finneman et al. (1993), and Ho and Fishbein (1994). Work with chiral 1-methylpropyl- and [l- H]ethyl-amine will provide information on the stereochemistry of these reactions. 

Assimilation tests for carbon compounds use yeast nitrogen base (YNB) without carbon sources, and the assimilation test for nitrogen compounds use yeast carbon base (YCB) without assimilable nitrogen sources. For the tests described, YNB without amine acids and ammonium sulfate is used (Anonymous, 1984). Carbon sources normally examined include a number of pentoses, hexoses, disaccharides, trisaccharides, polysaccharides, alcohols, organic acids, and glycosides as specified by Yarrow (1998). Nitrogen sources commonly tested include nitrate, nitrite, ethyl-amine hydrochloride, cada-verine dihydrochloride, L-lysine, imidazole, glucosamine, creatine, and creatinine. When nitrite is used as a test compound, it is necessary to adjust the pH of the medium to 6.5 because toxic nitrous acid is formed at pH <6.0. 

Ethanol amine dinitrate Ethylene diamine diperchlorate Ethylene glycol dinitrate Ethyl hydroperoxide Ethyl nitrate Ethyl nitrite Ethyl perchlorate... 

It is prepd by the action of methylamine on 4-chloro-l-nitrobenzene (Ref 5) by the action of methyl iodide (Ref 6), or methyl sulfate on 4-nit roaniline (Ref 7) or by the hydrolysis of 4-nitro-N-methylformanilide with hot coned aq HC1 (Ref 8). In a study of the effect of nitric acid concn on the prods of the nitration of N,N-dimethylaniline to form Tetryl, it was isolated in low yield by the action of nitric acid, d 1.046g/cc, plus Na nitrite on N,N-dimethylaniline (Ref 10). A eutectic mixt with N-ethyl-4-nitroaniline has been patented as a stabilizer for NC (Ref 12). Studies at NPF indicate that 4-nitro-N-methyl-aniline is superior to Centralite, 2-nitrodiphenyl-amine, or Acardite in stabilizing. NC Refs 1) Beil 12, 586, (295) 1125 ... 

The diazotization of heteroaromatic amines is basically analogous to that of aromatic amines. Among the five-membered systems the amino-azoles (pyrroles, diazoles, triazoles, tetrazoles, oxazoles, isooxazoles, thia-, selena-, and dithiazoles) have all been diazotized. In general, diazotization in dilute mineral acid is possible, but diazotization in concentrated sulfuric acid (nitrosylsulfuric acid, see Sec. 2.2) or in organic solvents using an ester of nitrous acid (ethyl or isopentyl nitrite) is often preferable. Amino derivatives of aromatic heterocycles without ring nitrogen (furan and thiophene) can also be diazotized. 

Several approaches to the 1,2,3-triazole core have been published in 2000. Iodobenzene diacetate-mediated oxidation of hydrazones 152 led to fused 1,2,3-triazoloheterocycles 153 <00SC417>. Treatment of oxazolone 154 with iso-pentyl nitrite in the presence of acetic acid gave 1,2,3-triazole 155, a precursor to 3-(W-l,2,3-triazolyl)-substituted a,P-unsaturated a amino acid derivatives <00SC2863>. Aroyl-substituted ketene aminals 156 reacted with aryl azides to provide polysubstituted 1,23-triazoles 157 <00HC387>. 2-Aryl-2T/,4/f-imidazo[43-d][l,2,3]triazoles 159 were prepared from the reaction of triethyl AM-ethyl-2-methyl-4-nitro-l//-imidazol-5-yl phosphoramidate (158) with aryl isocyanates <00TL9889>. 

The sensor did not respond to volatile compounds such as acetic acid, ethyl alcohol, and amines (diethylamine, propylamine, and butylamine) or to nonvolatile nutrients such as glucose, amino acids, and metal ions (potassium and sodium ions). Therefore, the selectivity of this microbial sensor was satisfactory in the presence of these different substances. The current output of the sensor was almost constant for more than 21 days and 400 assays. The microbial sensor can be used to assay sodium nitrite for a long period. In the same experiments the concentration of sodium nitrite was determined by both the sensor proposed and the conventional method (dime-thyl-a-naphtylamine method). A good correlation was obtained between the sodium nitrite concentrations determined by the two methods (correlation coefficient 0.99). 

A solution of sodium nitrite (3.28 g, 48 mmol) in water (20 ml) was added to a solution of the preceding amine hydrochloride (10.0 g, 48 mmol), in concentrated HCI (40 ml), at such a rate that the temperature did not exceed -10°C. After addition was complete the solution was stirred at 0°C for 0.25 h and then added portionwise to a rapidly stirred solution of SnCI2 x 2H20 (40 g) in concentrated HCI (40 ml). The solution was warmed to room temperature and basified with 20% aqueous NaOH solution. The solution was extracted with ethyl acetate (3 x 250 ml) and the combined extracts dried (MgS04) and filtered. The solution was evaporated to dryness to give the desired hydrazine (5.0 g, 56%) m.p. 109°-112°C. 

Aliphatic and aromatic amines react with nitrous acid to form N-nitroso derivatives. For example, dimethylamine hydrochloride on treatment with sodium nitrite and hydrochloric acid is converted to nitrosodimethyl amine in 90% yield. In like manner, N-nitrosomethylaniline is synthesized from N-methylaniline in 93% yield. The ready formation of these derivatives and the easy reconversion to the amine by reduction affords an advantageous procedure for separating secondary amines from primary and tertiary amines, as shown in the synthesis of N-ethyl-m-toluidine and other N-alkyl derivatives by the alkylation of w-toluidine. ... 

Several preparations of salts of the czs-dinitrobis(ethyl-enediamine)cobalt(III) ion have been reported in the literature. The most usual is that of Werner/ modified by Holtzclaw, Sheetz, and McCarty, beginning with potassium hexanitrocobaltate(III). However, this method makes use of a starting material which is difficult to prepare in high purity and to dry thoroughly, involves critical temperature control, and produces a yield of about 15%. The following procedure, which utilizes ethylenedi-amine)cobalt(III) chloride as the starting material, provides a 60% yield of cfs-dinitrobis(ethylenediamine)cobalt-(III) nitrite. The nitrite is then easily converted to the nitrate. 

Radical 80 has been prepared as its perchlorate salt by anodic oxidation in ethyl acetate in the presence of hthium perchlorate. The reactivity toward nucleophiles of material so prepared was investigated nitrite and nitrate ions give 2-nitrodibenzo[l,4]dioxin although the mechanisms of the reactions are not clear. Pyridine gives 7V-(2-dibenzo[l,4]dioxinyl)pyridinium ion (84). Other nucleophiles acted as electron donors and largely reduced 80 back to the parent heterocycle they included amines, cyanide ion and water. In an earlier study, the reaction of 80 with water had been examined and the ultimate formation of catechol via dibenzo[l,4]dioxin-2,3-dione was inferred. The cation-radical (80) has been found to accelerate the anisylation of thianthrene cation-radical (Section lII,C,4,b) it has been found to participate in an electrochemiluminescence system with benzo-phenone involving phosphorescence of the latter in a fluid system, and it has been used in a study of relative diffusion coefficients of aromatic cations which shows that it is justified to equate voltammetric potentials for these species with formal thermodynamic redox potentials. The dibenzo[l,4]dioxin semiquinone 85 has been found to result from the alkaline autoxidation of catechol the same species may well be in-... 

The reaction is effected either by conducting gaseous nitrous acid into the boiling alcohol solution of the amine, or by heating the amine with alcohol saturated with ethyl nitrite or the boiling alcohol solution of the amine, acidified with sulphuric add, may be treated with sodium nitrite. 

ACIDO SALICILICO (Spanish) (69-72-7) Combustible solid (flash point 315°F/157°C). Dust or powder forms explosive mixture in air. Reacts with strong oxidizers, ethyl nitrite, iodine, iron salts, lead diacetate. Incompatible with sulfuric acid, alkalis, ammonia, aliphatic amines, alkanolamines, isocyanates, alkylene oxides, epichlorohydrin. Flow or agitation of substance may generate electrostatic charges due to low conductivity. 

ETHYL NITRITE or ETHYL NITRITE SOLUTION (109-95-5) Thermally unstable. Heat around or above 190 F/88°C can cause explosive decomposition (may not need air or oxygen). Decomposes in air, sunlight, or moisture. Forms explosive mixture with air (flash point —31°F/—35°C). A powerful oxidizer. Violent reaction with acids, acid fumes, amines, ammonia, cyanides, reducing agents, other strong oxidizers, salts. 

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