Iodides mono

C[ 1h17n o3+ I- h2o 5 -Deoxy-5 -(methylammonium)adenosine iodide, mono- MAADIM10 30 462... 

CADMIUM POTASSIUM IODIDES, Mono = CdI,.KI.H,0, Di= CdI2.2KI.2HsO. 

Substitution Derivatives of Ethyl Malonate, Ethyl malonate resembles ethyl acetoacetate in that it gives rise to mono- and di-substituted derivatives in precisely similar circumstances. Thus when ethanolic solutions of ethyl malonate and of sodium ethoxide are mixed, the sodium derivative (A) of the enol form is produced in solution. On boiling this solution with an alkyl halide, e.g, methyl iodide, the methyl derivative (B) of the keto form is obtained. When this is treated again in ethanolic solution with sodium ethoxide, the... 

Mono-, di-, and trivalent bromides and iodides may be made by methods similar to the chlorides. The lower valence salts also disproportionate in water. Indium trifluoride [7783-52-0] InF., is sparingly soluble in water. It forms an ammonium double salt, SNH F TnF. [15273-84-4] which decomposes on heating to indium nitride [25617-98-5] InN. 

Perfluoroallyl fluorosulfonate is converted to perfluoroallyl bromide or iodide in 56 or 75% yield, respectively, by reaction with the potassium halide in mono-glyme at room temperature [S5]... 

Deactivation (weak) from the adjoining ring does not prevent facile disubstitution of 4-methyl- and 4-phenyl-2,7-dichloro-1,8-naphthyridines wdth alkoxides (65°, 30 min), p-phenetidine (ca. 200°, 2 hr), hydrazine hydrate (100°, 8 hr), or diethylaminoethylmer-captide (in xylene, 145°, 24 hr) mono-substitution has not been reported. Nor does stronger deactivation prevent easy 2-oxonation of 5,7-dimethoxy-l-methylnaphthyridinium iodide wdth alkaline ferricyanide via hydroxide ion attack adjacent to the positive charge and loss of hydride ion by oxidation. 

Cycloaddition of 2-nitrosopyridine 48 with nitrile oxides can give either di-A -oxides such as 49 or 3-mono-A -oxides such as 50 (93JHC287). In general, greater electron withdrawing character in the aromatic substituent appears to favor formation of the di-A -oxides. Sulfur ylides such as compound 51 are obtained from aryl isothiocyanates and l-amino-2-methylthiopyridinium iodides (84JCS(P1)1891) nitrogen ylides can be obtained from a similar reaction (86H(24)3363). 

Pure tin is completely resistant to distilled water, hot or cold. Local corrosion occurs in salt solutions which do not form insoluble compounds with stannous ions (e.g. chloride, bromide, sulphate, nitrate) but is unlikely in solutions giving stable precipitates (e.g. borate, mono-hydrogen phosphate, bicarbonate, iodide) . In all solutions, oxide film growth occurs and the potential of the metal rises. Any local dissolution may not begin for several days but, once it has begun, it will continue, its presence being manifested... 

Determination of nitrate as nitron nitrate Discussion. The mono-acid base nitron, C20H16N4, forms a fairly insoluble crystalline nitrate, C20H 16N4,HN03 (solubility is 0.099 g L 1 at about 20 °C), which can be used for the quantitative determination of nitrates [see Section 11.11(E)]. The sulphate and acetate are soluble so that precipitation may be made in sulphuric or acetic (ethanoic) acid solution. Perchlorates (0.08 g), iodides (0.17 g), thiocyanates (0.4 g), chromates (0.6 g), chlorates (1.2g), nitrites (1.9 g), bromides (6.1 g), hexacyanoferrate(II), hexacyanoferrate(III), oxalates, and considerable quantities of chlorides interfere, and should be absent. The figures in parentheses are the approximate solubilities of the nitron salts in g L-1 at about 20 °C. 

Pyrazolotriazine 253 was prepared (88JOC887) by coupling 3-diazopyrazole 250 with isopropylidene malonate 251 via 252. Methylation of253 with methyl iodide in the presence of methanolic potassium hydroxide gave pyrazolotriazines 255 and 256, whereas mono N-methyl derivative 254 was prepared (88JOC887) by the action of dimethyl sulfate on 253 (Scheme 55). 

Preparation. By the action of liq ammonia on S in the presence of Ag iodide. The N4S4 is isolated by filtn of the Ag sulfide ppt, evapn of the filtrate and recrystn from CS2. Also, by passing dry ammonia through S mono- or dichloride, dissolved in a non-aq solvent such as bz, CC14, etc or by the interaction of vapors of ammonia and S dichloride (Refs 2,3,4, 5, 7,8,9,16, 17 18)... 

Reaction of the anion derived from the tosyl imide of l,3,S-trithiane with alkyl iodides gives a mixture of the mono- and di- alkylated products, in which anti stereochemistry predominates. The analogous 1,3-dithiane derivative is only monoalkylated <96JCS(P1)313>. 

More recently, a study with di- and mono-carbene Pd(II) complexes has demonstrated that the Sonogashira coupling of activated and non-activated aryl iodides can be carried out in an aqueous, aerobic medium and in the absence of amines. These results suggest that the moisture-sensitive copper-acetylide may not be present in this particular transformation, and that a Pd-acetyhde could be formed by deprotonation of the coordinated alkyne instead of transmetallation [130]. 

Indium(I) iodide serves as a two electron reducing agent to promote a Ni-catalyzed allylation of benzaldehyde with 1,3-dienes [23]. In the presence of a catalytic amount of Ni(acac)2 and a stoichiometric amount of Ini, 1,3-butadiene reacts with 2 equiv. of benzaldehyde to provide a mixture of a 1,4-diol 28 and 1,6-diol 29 and/or with 1 equiv. of benzaldehyde to give 27 (Eq. 8). The product distribution of 27-29 markedly depends on the solvent, the ligand, and the additive employed (Table 2). The combination of Ni(acac)2, PPI13, and 3 equiv. of water in DMI provides the 1,4-diol 28 as the major product (run 1). Under similar conditions, dppb dramatically changed the reaction course and the mono-allylation product 27 is produced exclusively (run 2). In contrast to these, the reaction in dry THF provides the 1,6-diol 29 in excellent yield (rim 3). 

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