Hydroiodic acid, preparation

Cognate preparation taken as one intended for HI (hydroiodic acid, Hey If it works for HI, it probably works for HBr). 

Hydroiodic acid, the colorless solution formed when hydrogen iodide gas dissolves in water, is prepared by reaction of iodine with hydrogen sulfide or hydrazine or by an electrolytic method. Typically commercial hydroiodic acid contains 40—55% HI. Hydroiodic acid is used in the preparation of iodides and many organic iodo compounds. 

The aHphatic iodine derivatives are usually prepared by reaction of an alcohol with hydroiodic acid or phosphoms trHodide by reaction of iodine, an alcohol, and red phosphoms addition of iodine monochloride, monobromide, or iodine to an olefin replacement reaction by heating the chlorine or bromine compound with an alkaH iodide ia a suitable solvent and the reaction of triphenyl phosphite with methyl iodide and an alcohol. The aromatic iodine derivatives are prepared by reacting iodine and the aromatic system with oxidising agents such as nitric acid, filming sulfuric acid, or mercuric oxide. 

Methylene iodide [75-11-6], CH2I2, also known as diio dome thane, mol wt 267.87, 94.76% I, mp 6.0°C, and bp 181°C, is a very heavy colorless Hquid. It has a density of 3.325 g/mL at 20°C and a refractive index of 1.7538 at 4°C. It darkens in contact with air, moisture, and light. Its solubiHty in water is 1.42 g/100 g H2O at 20°C it is soluble in alcohol, chloroform, ben2ene, and ether. Methylene iodide is prepared by reaction of sodium arsenite and iodoform with sodium hydroxide reaction of iodine, sodium ethoxide, and hydroiodic acid on iodoform the oxidation of iodoacetic acid with potassium persulfate and by reaction of potassium iodide and methylene chloride (124,125). Diiodoform is used for determining the density and refractive index of minerals. It is also used as a starting material in the manufacture of x-ray contrast media and other synthetic pharmaceuticals (qv). 

Lithium Iodide. Lithium iodide [10377-51 -2/, Lil, is the most difficult lithium halide to prepare and has few appHcations. Aqueous solutions of the salt can be prepared by carehil neutralization of hydroiodic acid with lithium carbonate or lithium hydroxide. Concentration of the aqueous solution leads successively to the trihydrate [7790-22-9] dihydrate [17023-25-5] and monohydrate [17023-24 ] which melt congmendy at 75, 79, and 130°C, respectively. The anhydrous salt can be obtained by carehil removal of water under vacuum, but because of the strong tendency to oxidize and eliminate iodine which occurs on heating the salt ia air, it is often prepared from reactions of lithium metal or lithium hydride with iodine ia organic solvents. The salt is extremely soluble ia water (62.6 wt % at 25°C) (59) and the solutions have extremely low vapor pressures (60). Lithium iodide is used as an electrolyte ia selected lithium battery appHcations, where it is formed in situ from reaction of lithium metal with iodine. It can also be a component of low melting molten salts and as a catalyst ia aldol condensations. 

The reaction proceeds quantitatively and the hydroiodic acid can be removed by repeated distillation at 5.3 kPa (40 mm Hg), leaving pure H2PO2 as the product. Phosphinic acid may also be prepared by the treatment of barium hypophosphite [14871-79-5] with a stoichiometric quantity of sulfuric acid to precipitate barium sulfate. 

Aluminum iodide [7884-23-8] AIL, is a crystalline soHd with a melting poiat of 191°C. The presence of free iodine ia the anhydrous form causes the platelets to be yellow or brown. The specific gravity of this soHd is 3.98 at 25°C. Aluminum iodide hexahydrate [10090-53-6] AIL -6H20, and aluminum iodide pentadecahydrate [65016-30-0], AIL -15H20, are precipitated from aqueous solution. They may be prepared by the reaction of hydroiodic acid [10034-85-2], HI, with aluminum or aluminum hydroxide. 

Other Reactions. Primary amyl alcohols can be halogenated to the corresponding chlorides by reaction with hydrogen chloride in hexamethylphosphoramide (87). Neopentyl chloride [753-89-9] is formed without contamination by rearrangement products. A convenient method for preparing / f/-amyl bromide and iodide involves reaction of / f/-amyl alcohol with hydrobromic or hydroiodic acid in the presence of Li or Ca haUde (88). The metal haUdes increase the yields (85 —95%) and product purity. 

Bismuth ttiiodide may be prepared by beating stoichiometric quantities of the elements in a sealed tube. It undergoes considerable decomposition at 500°C and is almost completely decomposed at 700°C. However, it may be sublimed without decomposition at 3.3 kPa (25 mm Hg). Bismuth ttiiodide is essentially insoluble in cold water and is decomposed by hot water. It is soluble in Hquid ammonia forming a red triammine complex, absolute alcohol (3.5 g/100 g), benzene, toluene, and xylene. It dissolves in hydroiodic acid solutions from which hydrogen tetraiodobismuthate(Ill) [66214-37-7] HBil 4H2O, may be crystallized, and it dissolves in potassium iodide solutions to yield the red compound, potassium tetraiodobismuthate(Ill) [39775-75-2] KBil. Compounds of the type tripotassium bismuth hexaiodide [66214-36-6] K Bil, are also known. 

Attempts to prepare this substance by reduction of dioxotetrahydro-1,3,5-triazine with sodium amalgam,hydroiodic acid, or tin in acetic acid, were accompanied by hydrolytic cleavage of the ring. Only... 

This procedure for the synthesis of ethyl 3-nitroacrylate is essentially that of Stevens and Emmons.2 Four major changes have been introduced by the submitters rapid introduction of dinitrogen tetroxide no purification of the intermediate nitro iodo ester use of dry, finely powdered sodium acetate for elimination of hydroiodic acid and percolation of the final product through a mat of alumina. With these modifications, the preparation is reproducible and highly efficient (80-90% overall). 

Another reliable method of halopyrimidine synthesis is dehydroxy-halogenation . Refluxing pyrimidinones 10 and 13 with phosphorus oxychloride was followed by treating the resulting chloropyrimidines with hydroiodic acid to afford iodopyrimidine 11 and 14, respectively [10, 11]. 4-Chloropyrimidinone 13, on the other hand, was prepared by direct halogenation of pyrimidone 12. 

Sample preparation is rather involved. A sample of urine or fecal matter is obtained and treated with calcium phosphate to precipitate the plutonium from solution. This mixture is then centrifuged, and the solids that separate are dissolved in 8 M nitric acid and heated to convert the plutonium to the +4 oxidation state. This nitric acid solution is passed through an anion exchange column, and the plutonium is eluted from the column with a hydrochloric-hydroiodic acid solution. The solution is evaporated to dryness, and the sample is redissolved in a sodium sulfate solution and electroplated onto a stainless steel planchette. The alpha particles emitted from this electroplated material are measured by the alpha spectroscopy system, and the quantity of radioactive plutonium ingested is calculated. Approximately 2000 samples per year are prepared for alpha spectroscopy analysis. The work is performed in a clean room environment like that described in Workplace Scene 1.2. 

Iodine is known to catalyze the condensation of aldehydes, benzyl carbamate and allyltrimethylsilane to homoallylic amines. However, in this case the involvement of an in sitn prepared [MejSi] species was suggested to be the active catalyst [235], An iodine catalyzed acetalization of carbonyl compounds was reported, where the active catalyst was believed to be hydroiodic acid [236],... 

Preparation of Hydroiodic Acid. Perform the experiment in a fume cupboardl) Assemble an apparatus as shown in Fig. 56. Put 2 g of iodine and 0.5 g of red phosphorus into test tube 1. Pour 3-5 ml of water into test tube 4. The opening of the offtake tube must be as close as possible to the surface of the water in the receiver. Why must it not be submerged into the water ... 

Prepare zinc bromide and iodide in the same way, using hydro-bromic and hydroiodic acids instead of hydrochloric acid. 

Preparation of 3 5-diiodo-4-(4 -hydroxyphenoxy)phenylacetic acid (diacid) A solution of ethyl 3 5-diiodo-4-(4 -methoxyphenoxy)phenyl acetate (9.5 g) in acetic acid (60 ml) was heated under reflux with hydroiodic acid (SG 1.7, 50 ml) and red phosphorus (0.5 g) for 1 hour. The hot solution was filtered and the filtrate concentrated at 50°C and 15 mm of mercury to above 20 ml. The residue was treated with water (70 ml) containing a little sodium thiosulfate to decolorize the product. The solid was collected by filtration and purified by the method of Harington and Pitt-Rivers [Biochem. J. (1952), Vol. 50, page 438], Yield 8.36 g (95%). After crystallization from 70% (v/v) acetic acid it melted at 219°C. 

Iodine sol It is prepared by oxidising hydroiodic acid with iodic acid, when a purple colloidal solution of iodine is obtained. 

Method 1 Preparation of 46% Hydroiodic acid from Iodine and Hydrogen Sulfide gas... 

Summary Concentrated hydroiodic acid can be prepared by reacting iodine crystals with hydrogen sulfide gas in the presence of water. The acid should be used within a week of preparation. 

Summary Inositol nitrate is prepared by first, reacting quebrachitol with hydroiodic acid. The resulting product, inositol, is then treated with a nitrating acid. The inositol nitrate is then separated by decantation, and then dried over anhydrous sodium sulfate. Commercial Industrial note For related, or similar information, see Serial No. 474,067, March 22nd, 1932, by Hercules Powder Company, to Willard Crater, Succasunna, NJ. Part or parts of this laboratory process may be protected by international, and/or commercial/industrial processes. Before using this process to legally manufacture the mentioned explosive, with intent to sell, consult any protected commercial or industrial processes related to, similar to, or additional to, the process discussed in this procedure. This process may be used to legally prepare the mentioned explosive for laboratory, educational, or research purposes. 

The benzylisoquinolines represent one of the largest group of plant alkaloids (146,147), and catecholic representatives occur in mammalian tissues and fluids. The best known is tetrahydropapaveroline, shown in Fig. 22 as the (5) enantiomer TIQ 75a. Racemic material is often referred to as THP (160,161). The synthesis of TIQ 75a as well as that of the plant alkaloid (5)-N -bisnorreticuline (77a) is shown in Fig. 22. (5)-Tetrahydropapaverine (74a), on treatment with concentrated hydroiodic acid at 125 C, afforded TIQ 75a, which was fully characterized as its hydrochloride (156). TIQ 77a, possibly an intermediate in the plant biosynthesis of (5)-norreticuline (78a) and derived TIQs, and possibly mammalian morphine as well, was prepared from the benzyl-protected TIQ 76a. Deblocking was achieved over Pd catalyst and hydrogen in the presence of hydrochloric acid, leading directly to the hydrochloride salt of TIQ 77a... 

Benzoxathiol-2-one formation can in turn be the desired reaction pathway. This compound can be similarly prepared when a methoxy group is present at the 2 position [67]. The cycUsation is carried out using hydroiodic acid or pyridine hydrochloride as demethylating agents (Scheme 25). 

The nitrosamine (121) and especially diazonium salts (122) prepared from it, as well as their alkyl and aryl derivatives, are important synthetic intermediates (b-76MI4i200, p. 325). For conditions that decide between nitrosamine function or diazotization see (73jcS(P1)13S7). At room temperature or in concentrated hydrochloric acid nitrosamines derived from triazoles are unstable, and their decomposition products include chlorotriazoles (63LA(665)144) 5-nitrosamino-3-phenyl-l,2,4-triazole affords the 5-bromo compound with hydrobromic acid at 0 °C and reacts violently with hydroiodic acid (05lA(343)i). Thermal arylation with triazole nitrosamines is possible (73jcs(pi)i357). 

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