Iodine perchlorate

Solution a contained iodine and silver nitrate together with perchloric acid and sodium perchlorate. Solution contained sodium iodide, iodine, perchloric acid, and sodium perchlorate. Both solutions had a total ionic concentration equal to 1.0 mole 1 and contained the same concentration of perchloric acid. The object of the acid was to suppress the formation of h3qx)iodous acid according to the equilibrium... 

Diagnostically, perchlorate is used to assess the intrathyroidal organification of iodine. When perchlorate is administered after a dose of radioactive iodine, perchlorate washes out or discharges intrathyroidal inorganic iodide but does not affect covalently bound organic iodide. When organification is inadequate, there is a sharp decrease in intrathyroidal radioactive iodine after perchlorate administration. 

C. HIO is prepared by oxidation of iodine with perchloric acid, nitric acid, or hydrogen peroxide or oxidation of iodine in aqueous suspension to iodic acid by silver nitrate. Iodic acid is also formed by anodic oxidation at a platinum electrode of iodine dissolved in hydrochloric acid (113,114). 

Chlorine heptoxide is more stable than either chlorine monoxide or chlorine dioxide however, the CX C) detonates when heated or subjected to shock. It melts at —91.5°C, bods at 80°C, has a molecular weight of 182.914, a heat of vapori2ation of 34.7 kj/mol (8.29 kcal/mol), and, at 0°C, a vapor pressure of 3.2 kPa (23.7 mm Hg) and a density of 1.86 g/mL (14,15). The infrared spectmm is consistent with the stmcture O CIOCIO (16). Cl O decomposes to chlorine and oxygen at low (0.2—10.7 kPa (1.5—80 mm Hg)) pressures and in a temperature range of 100—120°C (17). It is soluble in ben2ene, slowly attacking the solvent with water to form perchloric acid it also reacts with iodine to form iodine pentoxide and explodes on contact with a flame or by percussion. Reaction with olefins yields the impact-sensitive alkyl perchlorates (18). 

As inert as the C-25 lactone carbonyl has been during the course of this synthesis, it can serve the role of electrophile in a reaction with a nucleophile. For example, addition of benzyloxymethyl-lithium29 to a cold (-78 °C) solution of 41 in THF, followed by treatment of the intermediate hemiketal with methyl orthoformate under acidic conditions, provides intermediate 42 in 80% overall yield. Reduction of the carbon-bromine bond in 42 with concomitant -elimination of the C-9 ether oxygen is achieved with Zn-Cu couple and sodium iodide at 60 °C in DMF. Under these reaction conditions, it is conceivable that the bromine substituent in 42 is replaced by iodine, after which event reductive elimination occurs. Silylation of the newly formed tertiary hydroxyl group at C-12 with triethylsilyl perchlorate, followed by oxidative cleavage of the olefin with ozone, results in the formation of key intermediate 3 in 85 % yield from 42. 

The oxidation of disulphones with iodine in aqueous perchloric acid apparently produces the corresponding sulphonic acid (equation 95)212. 

Note The TDM reagent can be used everywhere, where o-tolidine is employed. It can also be used on chromatograms, that have already been treated with ninhydrin, Pauly or ammonia perchlorate reagent or with iodine vapor [1]. Water may be used in place of 80% 2-propanol when making up solutions II, III and IV. The chlorine gas atmosphere in the chromatography chamber can also be created by pouring 5 ml hydrochloric acid (ca. 20%) onto 0.5 g potassium permanganate in a beaker such a chlorine chamber is ready for use after 2 min. 

Redox titrants (mainly in acetic acid) are bromine, iodine monochloride, chlorine dioxide, iodine (for Karl Fischer reagent based on a methanolic solution of iodine and S02 with pyridine, and the alternatives, methyl-Cellosolve instead of methanol, or sodium acetate instead of pyridine (see pp. 204-205), and other oxidants, mostly compounds of metals of high valency such as potassium permanganate, chromic acid, lead(IV) or mercury(II) acetate or cerium(IV) salts reductants include sodium dithionate, pyrocatechol and oxalic acid, and compounds of metals at low valency such as iron(II) perchlorate, tin(II) chloride, vanadyl acetate, arsenic(IV) or titanium(III) chloride and chromium(II) chloride. 

Iodine pentafluoride Metals Nitric acid Metals Nitrosyl fluoride Metals Perchloric acid Bismuth See other METALS... 

Iodine(VII) oxide Diethyl ether Lithium perchlorate Diethyl ether... 

See Other ACETYLENIC COMPOUNDS, IODINE COMPOUNDS, NON-METAL PERCHLORATES... 

See Other IODINE COMPOUNDS, IRRADIATION decomposition incidents, non-metal PERCHLORATES... 

Fluorine Hydrogen, or Hydrogen, Oxygen Fluorine perchlorate Hydrogen Iodine heptafluoride Carbon, etc. 

Iodine pentafluoride Metals Lead(IV) oxide Metals Nitryl fluoride Metals Potassium perchlorate Metal powders Sodium peroxide Metals See other metals... 

The self-ignition of sulfur with potassium chlorate or iodine(V) oxide at 145-160°C, and with potassium perchlorate at 385°C was studied using DTA [1], and combustion characterisitics of the mixtures were determined [2],... 

Dichlorine oxide Oxidisable materials Iodine pentafluoride Metals Iodine Metals Nitrosyl fluoride Metals Perchloric acid Antimony(III) compounds Potassium dioxide Metals Potassium permanganate Antimony, etc. 

Synthesis of Radical Cation Perchlorates and Subsequent Coupling with NucleophilesT Syntheses of the radical cation perchlorates of BP and 6-methylBP (12) were accomplished by the method reported earlier for the preparation of the perylene radical cation (13,14). More recently we have also synthesized the radical cation perchlorate of 6-fluoroBP (15). Oxidation of the PAH with iodine in benzene in the presence of AgClO. instantaneously produces a black precipitate containing the radical cation perchlorate adsorbed on Agl with... 

The oxidative cyclization of thioacylamidines 83 is one of the best methods for the synthesis of unsymmetrical 3,5-diaryl- or dialkyl-1,2,4-thiadiazoles 84 (Equation 23) <2004HOU277>. Typical oxidants used in the cyclization step include bromine, iodine, or nitric acid, and, more recently, hydrogen peroxide in the presence of perchloric acid has been used. N-Substituted thioacylamidines give rise to 1,2,4-thiadiazolium salts <1997JOC3480>. 

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