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Potassium borates bromide

Potassium borate Lavage with 2% sodium bicarbonate solution and administer 10-50 ml of 10% sodium thiosulfate solution intravenously at the rate of 3 ml min to reduce the bromate to the less toxic bromide ion. An alternative therapy is the administration of 100-500 ml of 1% sodium thiosulfate. Patients should be observed for development of renal toxicity and ototoxicity. [Pg.672]

Chloroprene Delrin 500F Texin 480AR Lead Chloride Sodium Thioarsenate Sodium Thioarsenate Sodium Thioarsenate Dowfax 2A1 Silicate Aroclor 5442 Lead Bromide Potassium Perborate Aroclor 1248 Potassium Borate Sodium Chromate Potassium Acetate Sodium Acetate Pyruvic Acid Perchloroethylene Perclene Tetrach loroethylene Dimethylacetamide Dimethyl Acetamide (N.N-) Methyl Abietate Aktivin... [Pg.1085]

Potassium Bicarbonate Potassium Borate Potassium Bromate Potassium Bromide ISO illlllllll lllllpll l 8 iiiiliilllilili iiiiiiiiiiiiiiiiliii temp. (S max. recem. DuPont Tefzel... [Pg.477]

DEKTAL DEVELOPER KODAK FIXER KODAK SHORT STOP POTASSIUM ALUM POTASSIUM BICARBONATE POTASSIUM BICHROMATE POTASSIUM BORATE POTASSIUM BROMATE POTASSIUM BROMIDE POTASSIUM CARBONATE POTASSIUM CHROMATE POTASSIUM CHLORATE POTASSIUM CHLORIDE POTASSIUM CYANIDE POTASSIUM DICHROMATE POTASSIUM FERRICYANIDE POTASSIUM FERROCYANIDE POTASSIUM FLUORIDE POTASSIUM HYDROXIDE POTASSIUM NITRATE POTASSIUM PERBORATE POTASSIUM PERCHLORATE POTASSIUM PERMANGANATE. 10% POTASSIUM SULFATE PROPANE PROPANE GAS PLATING SOLUTIONS BRASS CADMIUM COPPER GOLD INDIUM LEAD NICKEL RHODIUM SILVER TIN ZINC... [Pg.154]

Phosphata Ester Oils (C) Potassium Bicarbonate IBI Potassium Borate IC) Potassium Bromids (C) Potassium Carbonate IS) Potassium Chlorate (C) Potassium Chloride (C) Potssium Chromate (SI Potassium Cyanide (C) Potassium Oichromate (S) Potassium Ferricyanide IS) Potassium Hydroxide (SI Potassium Hypochlorite IS) Potassium Nitrate (Cl Potassium Oxalate IS) Potassium Permanganate IS) Potassium Sulfate IC) Potassium Sulfite ( 1 Prtstone (C)... [Pg.156]

Potassium Acetate Potassium Acid Sulfate Potassium Acid Tartrate Potassium Antimonate Potassium Bicarbonate Potassium Bichromate Potassium Bisulfate Potassium Bisulfite Potassium Bitartrate Potassium Borate Potassium Bromate Potassium Bromide Potassium Carbonate Potassium Chlorate Potassium Chloride Potassium Chromate Potassium Cyanide Potassium Dichromate Potassium Ferricyanide Potassium Ferrocyanide Potassium Fluoride Potassium Hexacyanoferrate (III) Potassium Hydrogen Carbonate Potassium Hydrogen Sulfate Potassium Hydrogen Sulfite Potassium Hydroxide Potassium Hypochlorite Potassium Hyposulfite Potassium lodate Potassium Iodide Potassium Manganate Potassium Nitrate Potassium Perborate Potassium Perchlorate Potassium Permanganate Potassium Peroxydisulfate Potassium Persulfate... [Pg.3479]

In the sodium borate solution containing bromide, when the pH 4 buffer is added before the potassium iodate solution, titrations give low total residual chlorine concentrations. This loss increases with the amount of stirring time between the addition of the reagents. Even for a stirring time of 10 seconds, there is a loss of about 17% of the total residual chlorine. If the solution were stirred for 30 min, 85% of the chlorine would have disappeared. The concentration of total residual chlorine determined by the reference methods does not change throughout the experiment. This implies that this loss of chlorine does not occur in the reaction vessel, but in the titration cell as a result of the analytical procedure. [Pg.123]

The chlorides, bromides, iodides, and cyanides are generally vigorously attacked by fluorine in the cold sulphides, nitrides, and phosphides are attacked inihe cold or may be when warmed a little the oxides of the alkalies and alkahne earths are vigorously attacked with incandescence the other oxides usually require to be warmed. The sulphates usually require warming the nitrates generally resist attack even when warmed. The phosphates are more easily attacked than the sulphates. The carbonates of sodium, lithium, calcium, and lead are decomposed at ordinary temp, with incandescence, but potassium carbonate is not decomposed even at a dull red heat. Fluorine does not act on sodium borate. Most of these reactions have been quahtatively studied by H. Moissan,and described in his monograph, Lejiuor et ses composes (Paris, 1900). [Pg.13]

The primary advantage in the first step of the method described here (using 1-chlorobutane diluted in MeCN) is that it eliminates long reaction periods and allows the use of secondary alkyl halides without competitive elimination reactions. For example, the reaction of sec-butyl bromide with N-methylimidazole using the classical method (in neat alkyl halide) produces, along with the desired product, 20-30% of butenes and 1-methylimidazole hydrobromide. In the second step, the use of water as solvent allows the anion metathesis reaction to be quantitative in a very short time and allows the easy purification of the ionic liquids. Moreover, employing the potassium salt avoids the use of corrosive and difficult to handle hexafluorophosphoric acid and the expensive silver tetrafluoro borate. ... [Pg.253]

Some examples of attempted isolation of resulting borates such as tributyl 3-pyridyl-, 3-quinolyl-, or 4-isoquinolyl borates by quaternization of the ring nitrogen with various allylic bromides have been reported (87JHC377). Alternatively, diethyl(3-pyridyl)borane obtained by the method mentioned previously reacts with potassium cyanide, and then, with alkyl halides, to afford cyanoborate betaines (20) in high yields (83CPB4573) (Scheme 7). [Pg.147]

H,2Br]N4Ru, Ruthenium(III), tetraammine-dibromo-, cis-, bromide, 26 67 H 2C1]N4Ru, Ruthenium(III), tetraammine-dichloro-, cis-, chloride, 26 66 H,4B,K, Borate(l-), tetradecahydronona-, potassium, 26 1... [Pg.370]

Plating solution, chrome Potassium acid sulfate Potassum alum Potassum aluminum sulfate Potassium bicarbonate Potassium bichromate Potassium bifluoride Potassium bisulfate Potassium bisulfite Potassium bitartrate Potassium bromide Potassium carbonate Potassium chlorate Potassium chloride Potassium chromates Potassium citrate Potassium cyanate Silicone tetrachloride, dry Silicone tetrachloride, wet Silver bromide Silver chloride Silver cyanide Silver nitrate Silver sulfate Soap solutions Soda ash Sodium acetate Sodium benzoate Sodium bicarbonate Sodium bichromate Sodium bifluoride Sodium bisulfate Sodium bisulfide Sodium bisulfite Sodium borate Sodium bromate Sodium bromide Sodium carbonate... [Pg.557]

Olealkonium chloride Phenoxyisopropanol Phenyl benzoate Phenylmercuric acetate Phenylmercuric benzoate Phenylmercuric borate Phenylmercuric bromide Phenylmercuric chloride Phenylparaben o-Phenylphenol Piroctone olamine Polyaminopropyl biguanide Potassium benzoate Potassium butyl paraben Potassium caroate Potassium ethylparaben Potassium metabisulfite . Potassium methylparaben Potassium paraben Potassium o-phenylphenate... [Pg.5563]

Sodium borate I potassium bromide I tetra-n-butylammonium iodide a-Imido- from a-bromo-ketones... [Pg.368]

Only 11 elements can be considered major components of seasalt the cations sodium, potassium, magnesium, calcium and strontium, and the anions chloride, sulphate, bromide, hydrogen carbonate (carbonate), borate (borid acid) and fluoride. These major dissolved constituents (concentrations > 1 mg/kg in ocean waters) make up > 99 % of the soluble ionic species of seawater. The elemental ratios are relatively constant throughout the world ocean, and their concentrations change due to the addition or substruction of water only (concept of conservatism ). Therefore, it is possible to characterize the composition by determining only one constituent that is easy to measure and is conservative in its behaviour. An example is chlorinity (Cl, as defined in Section 11.2.4). [Pg.229]

Fig. 3-98. Separation of inorganic anions using a borate/gluconate buffer as an eluant. - Separator column TSK Gel IC-PW eluant 1.3 mmol/L Na2B407 + 5.8 mmol/L H3BO3 + 1.4 mmol/L potassium gluconate/acetonitrile (88 12 v/v), pH 8.5 flow rate 1.2 mL/min detection direct conductivity injection 100 pL anion standard (5 to 40 mg/L) peaks fluoride (1), chloride (2), nitrite (3), bromide (4), nitrate (5), orthophosphate (6), and sulfate (7) (taken from [26]). Fig. 3-98. Separation of inorganic anions using a borate/gluconate buffer as an eluant. - Separator column TSK Gel IC-PW eluant 1.3 mmol/L Na2B407 + 5.8 mmol/L H3BO3 + 1.4 mmol/L potassium gluconate/acetonitrile (88 12 v/v), pH 8.5 flow rate 1.2 mL/min detection direct conductivity injection 100 pL anion standard (5 to 40 mg/L) peaks fluoride (1), chloride (2), nitrite (3), bromide (4), nitrate (5), orthophosphate (6), and sulfate (7) (taken from [26]).
Methods reported this year for the reduction of alkyl halides to alkanes include the potassium-dicyclohexyl-18-crown-6 reduction of alkyl fluorides, sodium borohydride reduction of alkyl chlorides, bromides, and iodides (or sulphonate esters) under liquid-liquid phase-transfer conditions, and the selective reduction of tertiary alkyl, benzyl, and allyl halides with the borate (61). Continuing... [Pg.183]

See other pages where Potassium borates bromide is mentioned: [Pg.198]    [Pg.33]    [Pg.225]    [Pg.112]    [Pg.273]    [Pg.209]    [Pg.553]    [Pg.208]    [Pg.200]    [Pg.973]    [Pg.973]    [Pg.64]    [Pg.321]    [Pg.553]    [Pg.392]    [Pg.18]    [Pg.296]    [Pg.117]    [Pg.461]    [Pg.392]    [Pg.25]    [Pg.4794]    [Pg.411]    [Pg.234]    [Pg.352]    [Pg.411]    [Pg.84]    [Pg.94]   
See also in sourсe #XX -- [ Pg.235 , Pg.236 , Pg.237 ]



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