Phosphate ruthenium

M.H. Pournaghi-Azar and R. Sabzi, Preparation of a cobalt hexacyanoferrate film-modified aluminum electrode by chemical and electrochemical methods enhanced stability of the electrode in the presence of phosphate and ruthenium(III). J. Solid State Electrochem. 6, 553—559 (2002). 

The addition to a double bond is observed in aromatic substrates where the reaction is assisted by chelation. The initial success of such reactions was achieved with the double alkylation of phenol with ethene (Equation (2)).1 This reaction occurs at the or/ -positions selectively by using an orthometallated ruthenium phosphate complex 1. 

Tris(2,2 -bipyridine)iron(3+) ion, 14 549 Tris(2,2 -bipyridine)iron(2+) ion, 14 549 Tris(2,2 -bipyridyl)ruthenium(II) complex chemiluminescence reagent, 5 856-857 Tris(2,3-dibromopropyl) phosphate, 11 502 Tris(2,3-dihydroxypropyl)isocyanurate, 8 204... 

Campbell has studied the separation of technetium by extraction with tributyl phosphate from a mixture of fission products cooled for 200 days. Nearly complete separation of pertechnetate is achieved by extraction from 2 N sulfuric acid using a 45 % solution of tributyl phosphate in kerosene. Ruthenium interferes with the separation and is difficult to remove without loss of technetium other radioisotopes can be removed by a cation-exchange process. However, this separation procedure has not been widely applied because of the adverse influence of nitrate. 

Suitable conditions for the quantitative polarographic determination of technetium as pertechnetate are given by Miller et al. who propose a 0.1 M KCl solution of pH 10 or a phosphate buffer solution of pH 7. Since in pH 7 buffer the current is directly proportional to the concentration of technetium over the range of 0.1 to 1.1 ppm, this medium has been used for the determination of low concentrations of technetium in solutions of fission products by the standard addition technique. The half-wave potential of the used wave is —0.68 V vs. SCE. The reaction appears to be irreversible (Fig. 13). It has been found that neither rhenium, ruthenium nor other fission products interfere. However, tetraphenyl-arsonium chloride is reduced at a more positive potential than is pertechnetate therefore, (QH5) AsCl, if present, must be separated. 

Addition of various promoters to ruthenium-containing solutions can increase the overall rate of CO reduction, but the most remarkable effect is the change in selectivity to ethylene glycol. The effects of several potassium salts are illustrated in Table XVII. The acetate, phosphate, and fluoride... 

J. (n4-l, 5-CYCLOOCTADIENE)TETRAKIS(METHYL-HYDRAZINE)RUTHENIUM(II) BIS[HEXAFLUORO-PHOSPHATE(l -)]... 

The non-specific alkaline phosphatases present in bone and calcifying cartilage have several properties in common. The ATPases concerned in the formation of different hard tissues seem to be isozymes. It could be shown that two enzymes capable of degrading ATP exist. One of them can be inhibited by levamisole and R 8231 and is probably identical with non-specific alkaline phosphates. The activity of the other enzyme, tentatively named Ca-ATPase , is dependent on the presence of Ca2+ or Mg2+ and is activated by these ions. The Ca-ATPase is unaffected by ouabain and ruthenium red. It may be speculated that the Ca-ATPase is concerned with the transmembranous transport of Ca2+-ions to the mineralization front229. ... 

Amino-l,2,4-benzotriazine 1,2-dioxide Thin layer chromatography Thymidine-5 -phosphate iV,iV,iV, iV -Telramclhylphcnylcncdiamine Tetranitromethane 3,5,4 -Trihydroxy-frans-stilbene 2-Amino-2-hydroxy-l, 3-propanediol Time-resolved light-scattering p-[meso-5-5,10,15,20-Tetra(pyridyl)porphyrin]tetra kis[ (ns-(bipyridine) chloride ruthenium(II)]... 

Beer, P. D., Szemes, F., Remarkable chloride over dihydrogen phosphate anion selectivity exhibited by novel macrocyclic bis [ruthenium(II) bipyridyl] and ruthenium(II) bipyridyl-metallocene receptors. J. Chem. Soc., Chem. Commun. 1995, 2245-2247. 

In order to reduce the time needed to perform a complete kinetic resolution Lindner et al53 reported the use of the allylic alcohol 30 in enantiomerically enriched form rather than a racemic mixture in kinetic resolution. Thus, the kinetic resolution of 30 was performed starting from the enantiomerically enriched alcohol (R) or (S)-30 (45%) ee obtained by the ruthenium-catalyzed asymmetric reduction of 32 with the aim to reach 100 % ee in a consecutive approach. Several lipases were screened in resolving the enantiomerically enriched 30 either in the enantioselective transesterification of (<5)-30 (45% ee) using isopropenyl acetate as an acyl donor in toluene in non-aqueous medium or in the enantioselective hydrolysis of the corresponding acetate (R)-31, (45% ee) using a phosphate buffer (pH = 6) in aqueous medium. An E value of 300 was observed and the reaction was terminated after 3 h yielding (<5)-30 > 99% ee and the ester (R)-31 was recovered with 86% ee determined by capillary GC after 50 % conversion. 

Treatment with the nickel(II) complex of the tripeptide glycine-glycine-histidine in the presence of magnesium monoperoxyphthalate Visible light irradiation in the presence of tris(bipyridyl)ruthenium(II) dication and ammonium persulfate Ethylmercury phosphate Fluorescein... 

Introduction of another ruthenium bipyridine moiety or bridging metallocene (ferrocene, cobaltocenium) results in sensors that specifically bind chloride anions (Figure 16.15). The structural modification of the amide receptor results in a decease in cavity dimensions and significant rigidity of the macrocycle. Therefore it cannot accommodate hydrogen phosphate anions, but only much smaller CF [45, 46]. 

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