Formaldehyde and nitrogen

Chemical/Physical. The atmospheric oxidation of ethyl ether by OH radicals in the presence of nitric oxide yielded ethyl formate as the major product. Minor products included formaldehyde and nitrogen dioxide. In the absence of nitric oxide, the products were ethyl formate and acetaldehyde (Wallington andjapar, 1991). 

Pollard, F. H., and Wyatt, P. M. H Reactions Between Formaldehyde and Nitrogen Dioxide Part III, The Determination of Flame Speeds, Transactions of the Faraday Society, Vol. 45, No. 328,... 

The foam-scrubbing technique has been studied for a variety of gases, including ammonia, sulfur dioxide, hydrogen sulfide, formaldehyde, and nitrogen oxides. Liquid and solid streams that have been experimented with include sulfuric acid fog and mist, dust, fly ash, and methylene blue. 

Traces of formaldehyde, present in neat end-capped polymer or produced by processing polymer under abusive conditions, detract from polymer stabihty. Commercial resins typically contain formaldehyde scavengers. Nitrogen compounds, especially amines and amides, epoxies, and polyhydroxy compounds, are particularly efficacious scavengers. 

Phosphoric Acid-Based Systems for Cellulosics. Semidurable flame-retardant treatments for cotton (qv) or wood (qv) can be attained by phosphorylation of cellulose, preferably in the presence of a nitrogenous compound. Commercial leach-resistant flame-retardant treatments for wood have been developed based on a reaction product of phosphoric acid with urea—formaldehyde and dicyandiamide resins (59,60). 

Compounds that induce bronchoconstriction include tobacco smoke, formaldehyde, and diethyl ether. Several other compounds, such as acidic fumes (e.g., sulfuric acid) and gases, such as ozone and nitrogen dioxide, as well as isocyanates, can cause bronchoconstriction. Also, cellular damage in the airways induces bronchoconstriction because of the release of vasoactive compounds. Frequently, different mechanisms work at the same time, provoking bronchoconstriction and increased secretion of mucus, both of which interfere with respiration. 

Recently, results of careful experiments were reported by Ito et a/.101 They claimed that formic acid, formaldehyde, and methanol, which had been previously reported as photoelectrochemical reduction products of carbon dioxide, were observed also by photolysis of cell materials, such as electrolytes, including 15-crown-5 ether, and epoxy resin, which has often been used as the molding material of semiconductor electrodes in aqueous solutions. Previously reported reduction products were obtained also under nitrogen with (Table 4) and without (Table 5) a p-GaP photocathode under illumination. These precise experiments under improved conditions, where no photolytic products were observed, gave the result that the main reduction product of carbon dioxide at a p-GaP photocathode in aqueous electrolytes was formic acid. Thus, many kinds of products reported in previous papers83,97,100 were suggested to be due to photolysis of cell materials. 

Many years later, Schwartz (Schwartz and Goverde, 1982 Voet and Schwartz, 1983) discovered that the synthesis of adenine via polymerisation of HCN can be accelerated by adding formaldehyde and other aldehydes. Reactions in the gas phase (nitrogen/methane atmosphere) promoted by electrical discharges led to the formation of cyanoacetylene in relatively good yields the latter reacts with urea to give various products, including cytosine (Sanchez et al., 1968). 

N-AryInitrones (XIII) formed by oxidation of N-hydroxy-N-methyl arylamines, show high reactivity toward carbon-carbon and carbon-nitrogen double bonds in non-aqueous media (21,203) (Figure 10). Under physiological conditions, however, it appears that N-arylnitrones exist as protonated salts that readily hydrolyze to formaldehyde and a primary N-hydroxy arylamine and efforts to detect N-arylnitrone addition products in cellular lipid, protein or nucleic acids have not been successful (204). Nitroxide radicals derived from N-hydroxy-MAB have also been suggested as reactive intermediates (150), but their direct covalent reaction with nucleic acids has been excluded (21). 

Gutehoffnungshiitte [Named after the company of that name in Oberhausen, Germany, now a subsidiary of MAN A.G., Munich] A process for oxidizing methane to formaldehyde, using nitrogen oxides as the oxidant and sodium borate as the catalyst. Operated at atmospheric pressure and 620°C. Developed in Germany during World War II and improved by R Nashan in 1951. 

Fathalla et al. reported that some [l,2,4]triazolo[4,3- ]quinazoles can be subjected to various transformations involving the triazole nitrogen atom <2000MOL1210>. Thus, treatment of 186 with formaldehyde and pyrrolidine... 

In the second example, N-dealkylation, oxidation of the carbon next to the nitrogen leads to a carbinolamine. This spontaneously leads to formaldehyde and an amine. The mechanism involves loss of a proton with electrons moving toward the electronegative nitrogen atom. The negative charge on the nitrogen is neutralized due to the addition of a proton from the environment. 

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