Barium chlorate chlorite

Potassium bichromate. Antimony sulfide Potassium permanganate. Powdered sugar Barium chlorate, Paraffln wax Potassium perchlorate. Cane sugar Sodium nitrate. Sulfur Sodium peroxide. Sulfur Sodium chlorite. Aluminum powder Magnesium chlorate. Aluminum powder Guanidine nitrate. Antimony powder Ammonium nitrate. Gasoline... [Pg.332]

Bleaching powder Sodium chlorite Sodium chlorate Potassium chlorate Barium chlorate Silver chlorate Ignition Ignition Ignition Ignition Ignition Ignition Sodium chromate Potassium chromate Ammonium dichromate Sodium dichromate Potassium dichromate Barium peroxide Smoke Smoke Smoke Smoke Smoke Smoke to... [Pg.263]

Impact sensitivities of mixtures of red phosphorus with various oxidants were determined in a direct drop-ball method, which indicated higher sensitivities than those determined with an indirect striker mechanism. Mixtures with silver chlorate were most sensitive, those with bromates, chlorates and chlorites were extremely sensitive, and mixtures with sodium peroxide and potassium superoxide were more sensitive than those with barium, calcium, magnesium, strontium or zinc peroxides. Mixtures with perchlorates or iodates had sensitivities comparable to those of unmixed explosives, such as lead azide, 3,5-dinitrobenzenediazonium-2-oxide etc. [Pg.1888]

K. G. Thurnlackh and K. F. von Hayn prepared a mixed soln. of potassium chlorate and chlorite by the action of potassium hydroxide free from chlorine on a soln. of chlorine dioxide. Light was carefully excluded, and the soln. was evaporated in vacuo at 45°-50°—potassium chlorate separated out first, and after further evaporation, alcohol was added, and the clear alcoholic soln. evaporated. Needle-like crystals of potassium chlorite, KC102, were obtained which deliquesced on exposure to air. As already indicated in connection with the preparation of the acid, G. Bruni and G. Levi made the potassium chlorite by reducing a soln. of potassium chlorate with oxalic acid and A. Reychler, sodium chlorite, by the action of chlorine dioxide on a soln. of sodium peroxide. Sodium chlorite, NaClQ2, can be also made by double decomposition by treating a soln. of barium chlorite with sodium sulphate and evaporating the clear soln. in vacuo. [Pg.283]

BENSULFOID (7704-34-9) Combustible solid (flash point 405°F/207°C). Finely divided dry materia forms explosive mixture with air. The vapor reacts violently with lithium carbide. Reacts violently with many substances, including strong oxidizers, aluminum powders, boron, bromine pentafluoride, bromine trifluoride, calcium hypochlorite, carbides, cesium, chlorates, chlorine dioxide, chlorine trifluoride, chromic acid, chromyl chloride, dichlorine oxide, diethylzinc, fluorine, halogen compounds, hexalithium disilicide, lampblack, lead chlorite, lead dioxide, lithium, powdered nickel, nickel catalysis, red phosphorus, phosphorus trioxide, potassium, potassium chlorite, potassium iodate, potassium peroxoferrate, rubidium acetylide, ruthenium tetraoxide, sodium, sodium chlorite, sodium peroxide, tin, uranium, zinc, zinc(II) nitrate, hexahydrate. Forms heat-, friction-, impact-, and shock-sensitive explosive or pyrophoric mixtures with ammonia, ammonium nitrate, barium bromate, bromates, calcium carbide, charcoal, hydrocarbons, iodates, iodine pentafluoride, iodine penloxide, iron, lead chromate, mercurous oxide, mercury nitrate, mercury oxide, nitryl fluoride, nitrogen dioxide, inorganic perchlorates, potassium bromate, potassium nitride, potassium perchlorate, silver nitrate, sodium hydride, sulfur dichloride. Incompatible with barium carbide, calcium, calcium carbide, calcium phosphide, chromates, chromic acid, chromic... [Pg.156]

Solymosi et al. (207) report that in general, at lower temperatures, solid chlorites disproportionate into chlorate and chloride ions. At higher temperatures, up to 400 C, sodium chlorite still undergoes disproportionation, whereas lead and barium chlorites explode violently to give mainly chloride ion and oxygen. [Pg.225]

Aly and Huang discussed the removal of several cations such as barium, iron, vanadium, and selenium, and several chlorine, fluorine, and cyanide compounds. More recently, activated carbons have also been used for the adsorptive removal of sulfides, nitrates, chlorides, chlorites, and chlorates, cyanides, " boric acid, borax, and borates, as well as certain metals such as lithium, cerium, iron, strontium, and dysposium from the aqueous phase. [Pg.300]