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Chlorine dioxide fluoride

Chlorine dioxide Copper Fluorine Hydrazine Hydrocarbons (benzene, butane, propane, gasoline, turpentine, etc) Hydrocyanic acid Hydrofluoric acid, anhydrous (hydrogen fluoride) Hydrogen peroxide Ammonia, methane, phosphine or hydrogen sulphide Acetylene, hydrogen peroxide Isolate from everything Hydrogen peroxide, nitric acid, or any other oxidant Fluorine, chlorine, bromine, chromic acid, peroxide Nitric acid, alkalis Ammonia, aqueous or anhydrous Copper, chromium, iron, most metals or their salts, any flammable liquid, combustible materials, aniline, nitromethane... [Pg.165]

Can spontaneously ignite when in contact with organic matter. Reacts with moist air to produce Chlorine (C10-A001), Hydrogen fluoride (C11-A031), and Chlorine dioxide. [Pg.281]

Calcium azide, 3936 f Carbon disulfide, 0560 Chlorine dioxide, 4042 Chloroacetylene, 0652 Chloryl perchlorate, 4104 Copper(I) azide, 4287 Cyanamide, 0404 Cyanoform, 1383 Cyanogen bromide, 0313 Cyanogen chloride, 0323 Cyanogen fluoride, 0323... [Pg.140]

Bromine bromate, 0276 Bromine dioxide, 0258 Bromine perchlorate, 0235 Bromine trioxide, 0259 Bromyl fluoride, 0239 Chlorine dioxide, 4042 Chlorine perchlorate, 4101 Chlorine trifluoride oxide, 3982 Chlorine trioxide, 4044 Chloryl hypofluorite, 3973 Chloryl perchlorate, 4104 Dichlorine oxide, 4095 Dichlorine trioxide, 4100 Dicyanogen AW -dioxidc. 0998 Dioxygen difluoride, 4320 Fluorine perchlorate, 3976 Hexaoxygen difluoride, 4327 Iodine dioxide trifluoride, 4334 Iodine(V) oxide, 4627 Iodine(VII) oxide, 4628 Oxygen difluoride, 4317 Perbromyl fluoride, 0240 Perchloryl fluoride, 3974... [Pg.185]

The injury caused by chlorine trifluoride is in part attributed to its hydrolysis products, including chlorine, hydrogen fluoride, and chlorine dioxide. Effects in humans have not been reported but may be expected to be very severe inhalation may cause pulmonary edema, and contact with eyes or skin may cause severe burns. [Pg.142]

G. S. Serullas treated potassium chlorate with an excess of hydrofluosilicic acid the clear liquid was decanted from the sparingly soluble potassium fluosilicate, the soln. evaporated below 30°, and filtered through glass powder J. J. Berzelius evaporated the acid liquid mixed with finely divided silica below 30° in air, or over cone, sulphuric acid and potassium hydroxide in vacuo. The excess of hydrofluoric acid was volatilized as silicon fluoride, and the clear liquid was then filtered from the excess of silica. R. Bottger treated sodium chlorate with oxalic acid whereby sparingly soluble sodium oxalate was formed J. L. Wheeler, and T. B. Munroe treated sodium chlorate with hydrofluosilicic acid and M. Brandau treated potassium chlorate with aluminium sulphate and sulphuric acid and precipitated the alum so formed with alcohol. Chloric acid is formed in many reactions with hypochlorous and chlorous acid for example, it is formed when an aq. soln. of chlorine or hypochlorous or chlorous acid decomposes in light. It is also formed when an aq. soln. of chlorine dioxide stands in darkness or in light. A mixture of alkali chlorate and chlorite is formed when an aq. soln. of an alkali hydroxide is treated with chlorine dioxide. [Pg.300]

Chlorine Dioxide See under Chlorine Oxides Chlorine Fluorides Although in 1891, H. Moissan (cited in Ref 2) easily prepd bromine iodine fluorides by direct action of the corresponding elements, he claimed that it was impossible to obt any chlorine fluoride. Other investigators among them Lebeau(1906, cited in Ref 2) and Ruff Zedner(1909 cited in Ref 2) also tried, but failed. It was not until 1928 that Ruff et al (Ref 3) succeeded in prepg the monocompd Chlorine Monofluoride, C1F, mw 54.46 colorless gas, fr p -154, bp 100.8, d 1.62 at -100° critical temp -14°, Q evapn 2.27 kcal/mol was prepd by action of si moist chlorine on fluorine at RT if the gases are dry they do... [Pg.25]

Yellow Organic vapors, chlorine, chlorine dioxide, hydrogen chloride, hydrogen fluoride, sulfur dioxide, or hydrogen sulfide (for escape only)... [Pg.598]

The Baxter Water Treatment Plant, Philadelphia, Pennsylvania, is a 12.35-m /s (282-MGD) conventional water treatment plant built in 1960. The plant supphes drinking water from the Delaware River to a population of over 800,000. Chemicals used in treatment include chlorine, ferric chloride or ferrous sulfate, hme, fluoride, and ammonia. Powdered activated carbon is used on demand for control of taste and odor, and chloride dioxide is used for control of THMs, tastes, and odors. The chlorine dioxide system was left over from the previous water treatment plant on that site. In the 1950s, it was used to oxidize phenolic compounds found in the watershed, which have since been eliminated. [Pg.387]


See other pages where Chlorine dioxide fluoride is mentioned: [Pg.878]    [Pg.878]    [Pg.210]    [Pg.165]    [Pg.165]    [Pg.878]    [Pg.878]    [Pg.210]    [Pg.165]    [Pg.165]    [Pg.87]    [Pg.465]    [Pg.121]    [Pg.411]    [Pg.793]    [Pg.300]    [Pg.377]    [Pg.377]    [Pg.959]    [Pg.71]    [Pg.257]    [Pg.229]    [Pg.1118]    [Pg.260]    [Pg.300]    [Pg.25]    [Pg.411]    [Pg.947]    [Pg.458]    [Pg.260]    [Pg.793]    [Pg.847]    [Pg.241]    [Pg.327]    [Pg.499]    [Pg.891]   
See also in sourсe #XX -- [ Pg.165 ]




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