1 Carbon dioxide hydrogen cyanide

Acrylonitrile Acetonitrile Carbon dioxide Hydrogen cyanide Acrolein... 

Irradiation of toluene (80 ppm) by UV light (A, = 200-300 nm) on titanium dioxide in the presence of oxygen (20%) and moisture resulted in the formation of benzaldehyde and carbon dioxide. Carbon dioxide concentrations increased linearly with the increase in relative humidity. However, the concentration of benzaldehyde decreased with an increase in relative humidity. An identical experiment, but without moisture, resulted in the formation of benzaldehyde, carbon dioxide, hydrogen cyanide, and nitrotoluenes. In an atmosphere containing moisture and nitrogen dioxide (80 ppm), cresols, benzaldehyde, carbon dioxide, and nitrotoluenes were the photoirradiation products (Ibusuki and Takeuchi, 1986). 

A third type of double-replacement reaction that occurs in aqueous solutions results in the formation of a gas. Some gases commonly produced in these reactions are carbon dioxide, hydrogen cyanide, and hydrogen sulfide. 

Carbon dioxide Hydrogen cyanide Triethylamine Acetic acid Cyclohexane Benzene Hydronium ion E-difluoroethene L-alanine D-alanine Nicotine Vitamin A... 

ETHYL ISOCYANATE (109-90-0) C1H5NCO Highly flammable liquid. Forms explosive mixture with air (flash point 12°F/-5°C Fire Rating 3). Decorrqjoses in water, forming toxic carbon monoxide, carbon dioxide, hydrogen cyanide, and... 

HAZARD RISK Highly flammable corrosive explosive hazardous decomposition or combustion by-products include carbon monoxide, carbon dioxide, hydrogen cyanide and/or nitrogen oxides vapors may travel long distances to source of ignition and flash back NFPA Code H4 F3 R2. 

HAZARD RISK Container explosion may occur with exposure to heat or flame emits toxic fumes under fire conditions decomposition emits carbon monoxide, carbon dioxide, hydrogen cyanide and nitrogen oxides NFPA Code not available. 

EXPLOSION and FIRE CONCERNS combustible NFPA rating (NA) reacts violently with alcohols and isocyanates hazardous polymerization will occur containers may explode under fire conditions incompatible with amines, alcohols, water, acids, strong alkalies, and heat heating to decomposition emits carbon monoxide, carbon dioxide, hydrogen cyanide, and oxides of nitrogen and sulfur use water spray, dry chemical powder, carbon dioxide, or foam for firefighting purposes. 

Levin, B.C. Paabo, M. Gurman, J.L. Clark, H.M. Yoklavich, M.F. Further Studies of the Toxicological Effects of Different Time Exposures to the Individual and Combined Fire Gases-Carbon Monoxide, Hydrogen Cyanide, Carbon Dioxide and Reduced Oxygen, Polyurethane 88. Proceedings of the 31— SPI Conference. Philadelphia, PA, 1988, p. 249-252. 

They et al. (1993) evaluated the degradation of aldicarb at nine different temperatures. When aldicarb was oxidized at a temperature range of 275-650 °C, the following reaction products were identified by GC/MS acetone, 2-methyl-2-propenenitrile, methylthiopropene, dimethyl disulfide, carbon dioxide, carbon monoxide, nitrous oxide, isocyanatomethane, hydrogen azide, sulfur dioxide, hydrogen cyanide, and 2-propenenitrile. 

Carbon monoxide, carbon dioxide, sulfur dioxide, hydrogen cyanide, particulates, nitrogen dioxide, benzoapryene, etc. from combustion sources including gas ranges, dryers, water heaters, kerosene heaters, fireplaces, wood stoves, garage, etc. Aminos from humidification equipment ... 

Carbon dioxide decomposes potassium ferrocyanide solution at 72° to 74° C., liberating hydrogen cyanide and precipitating ferrous potassium ferrocyanide.2 Continued passage of carbon dioxide through a boiling solution of potassium ferrocyanide results in the precipitation of ferric hydroxide and the formation of potassium carbonate and hydrogen cyanide, or its decomposition products, ammonia and formaldehyde.3... 

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