Amine-hydrogen work

The amine-hydrogen work at CRNL showed the superiority of methyl-amine as the exchange medium over ammonia or other amines, and... 

Hydrogenation of amides normally result in the formation of alcohols, whereas lactams give cyclic amines. The work presented in this paper is the first example that we are aware in which a lactam was hydrogenated by a ruthenium catalyst. To verify that acid promoted the lactam carbonyl hydrogenation, two... 

During the vacuum fractional distillation of bulked residues (7.2 t containing 30-40% of the bis(hydroxyethyl) derivative, and up to 900 ppm of iron) at 210-225°C/445-55 mbar in a mild steel still, a runaway decomposition set in and accelerated to explosion. Laboratory work on the material charged showed that exothermic decomposition on the large scale would be expected to set in around 210-230°C, and that the induction time at 215°C of 12-19 h fell to 6-9 h in presence of mild steel. Quantitative work in sealed tubes showed a maximum rate of pressure rise of 45 bar/s, to a maximum developed pressure of 200 bar. The thermally induced decomposition produced primary amine, hydrogen chloride, ethylene, methane, carbon monoxide and carbon dioxide. 

In any case, the treatment of the catalyst results in a more selective (regarding the formation of primary amine) hydrogenation of nitriles. This effect could be explained on a molecular basis by electronic (work function) and/or steric effects by strongly adsorbed species that function to partition the wide-open active surface of Ni and Co catalysts into smaller active sites composed of a controlled number of... 

Lithium aluminum hydride is a convenient reagent for reduction of nitro compounds, nitriles, amides, azides, and oximes to primary amines. Catalytic hydrogenation works also. Aromatic nitro compounds are reduced best by reaction of a metal and aqueous acid or with ammonium or sodium polysulfides (see Section 23-12B). Reduction of /V-substituted amides leads to secondary amines. 

General guidelines for choice of reagent for reductive amination use LiAlH4 when the imine or oxime is isolated. Use Na(CH3COO)3BH in solution when the imine or iminium ion is not isolated. Alternatively, catalytic hydrogenation works in most cases. 

Rather surprisingly alcohols are poor at reducing imines, yet TEAF works well. During our studies we rationalized that the TEAF system was sufficiently acidic (pH approximately 4) to protonate the imine (pK l approximately 6) and that it was an iminium that was reduced to an ammonium salt [14]. When an iminium was used in the I PA system, it was reduced albeit with a low rate and moderate enan-tioselectivity. Quaternary iminium salts were also reduced to tertiary amines. Hydrogen will not reduce ketones or imines using the CATHy catalysts, but hydrides such as sodium borohydride have been shown to work. 

Nitroparaffins with (Ph3P)3RuCl2 hydrogenate to secondary alkyl primary amines. Aqueous work-up procedures are not necessary the method is recommended for high catalyst turnovers and relatively mild reaction conditions. ... 

The aromatic-amine interaction is modeled as the interaction between C6H6 and H2NCH3. In this work, only the ar-type hydrogen bonding structures are considered. In this structure, the amine should reside over the benzene ring with one of its amine hydrogens pointing toward its aromatic it electrons (Fig. 12). 

Amine and phenolic antioxidants are considered free-radical scavengers. They probably work by the direct abstraction of amine hydrogen by the RO group. Increased steric hindrance at the 2 and 6 position of phenolic antioxidant has resulted in improved antioxidant performance. There may be an optimum amount of steric hindrance of the phenolic group, which should be matched to the oxidizable matrix polymer. This will allow a balanced interference of the radical chain process so that both propagating species, R and RO , are effectively neutralized. 

An example of this problem is provided by our work on the interaction of urea and thiourea with crown ethers[23]. Five crystal structures have been carried out on these systems (18-crown-6)(thiourea)2, [24] (18-crown-6)(urea)5, [25], (18-crown-6)(N-methylthiourea) [26], (18-crown-6)(chlorophenylurea)2, [27] and (18-crown-6)(thiourea)4 [28]. In all these structures there are intermolecular hydrogen bonds between the amine hydrogen atoms and the oxygen atoms in the 18-crown-6. The pattern of hydrogen bonds is different in the five structures. 

A different type of photoreaction in ILs has been studied by Jones and co-workers the photoreduction of benzophenones by primary amines. Prior work by Cohen demonstrated that photolysis of benzophe-none in benzene in the presence of sec-butylamine afforded benzopinacol (and an imine). This reaction proceeds through a radical pair formed by hydrogen-atom abstraction by the triplet excited state ben-zophenone from the amine. In the much more polar environment of an IL, the radical pair may instead undergo single electron transfer to form an iminium cation and a hydroxyl-substituted carbanion. Proton transfer from the cation to the anion will yield benzhydrol and an imine. 

The.effect of the entropy of activation was noted above for the quaternary pyridine salts (280 and 281). In future work, it may also be found to reflect the electrostatic or hydrogen-bonding interactions in transition states of amination reactions and the effect of reversible cationization of an azine-nitrogen. Brower et observed a substantial rate difference between piperidino-dechlorinations of 2-chloropyrimidine in petroleum ether and in alcohol due partly to the higher entropy of activation in the latter solvent (Table III, lines 3 and 4). 

Acetylene works Acrylates works Aldehyde works Aluminum works Amines works Ammonia works Anhydride works Arsenic works Asbestos works Benzene works Beryllium works Bisulfate works Bromine works Cadmium works Carbon disulfide works Carbonyl works Caustic soda works Cement works Ceramic works Chemical fertilizer works Chlorine works Chromium works Copper works Di-isocyanate works Electricity works Fiber works Fluorine works Gas liquor works Gas and coke works Hydrochloric acid works Hydrofluoric acid works Hydrogen cyanide works Incineration works Iron works and steel works... 

A better method for preparing primary amines is to use the azide synthesis, in which azjde ion, N3, is used for SN2 reaction with a primary or secondary alkyl halide to give an alkyl azide, RN3. Because alkyl azides are not nucleophilic, overalkylation can t occur. Subsequent reduction of the alkyl azide, either by catalytic hydrogenation over a palladium catalyst or by reaction with LiAlK4. then leads to the desired primary amine. Although the method works well, low-molecular-weight alkyl azides are explosive and must be handled carefully. 

Preeclampsia, Viagra and, 164 Prelog, Vladimir, 181 Prepolymer, epoxy resins and, 673 Priestley, Joseph, 245 Primary alcohol, 600 Primary amine, 916 Primary carbon. 84 Primary hydrogen, 85 Primary structure (protein), 1038 Primer strand (DNA), 1108 pro-R prochiralitv center, 316 pro-S prochirality center, 316 Problems, how to work, 27 Procaine, structure of, 32 Prochirality, 315-317 assignment of, 315-316 naturally occurring molecules and, 316-317... 

Nearly quantitative yields of acetonitrile can be obtained by passing mixtures of NH3 and acetylene over zircon at 400-500°C [225], over CviOy on Y-alumina at 360°C [226] or by passing mixtures of NH, acetylene and hydrogen at 400-420°C over a mixture of zinc and thorium oxides on silica [227] or at 300-450°C over zinc oxide or zinc sulfate or zinc chloride on silica [228, 229], In such reactions, the role of traces of water has often been questioned. However, acetonitrile could be obtained under rigorously anhydrous conditions, thus demonstrating the direct amination of acetylene with NH,. It was also reported that ethyUdeneimine can be obtained in up to 26% yield [225], However, in the Ught of more recent work [230, 231] the product was most probably 2,4,6-trimethyl-l,3,5-hexahydrotriazine. 

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