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Metals nonaqueous solvents

Metal organic decomposition (MOD) is a synthesis technique in which metal-containing organic chemicals react with water in a nonaqueous solvent to produce a metal hydroxide or hydrous oxide, or in special cases, an anhydrous metal oxide (7). MOD techniques can also be used to prepare nonoxide powders (8,9). Powders may require calcination to obtain the desired phase. A major advantage of the MOD method is the control over purity and stoichiometry that can be achieved. Two limitations are atmosphere control (if required) and expense of the chemicals. However, the cost of metal organic chemicals is decreasing with greater use of MOD techniques. [Pg.310]

N2O4 has been extensively studied as a nonaqueous solvent system and it is uniquely useful for preparing anhydrous metal nitrates and nitrato complexes (p. 468). Much of the chemistry can be rationalized in terms of a selfionization equilibrium similar to that observed for... [Pg.456]

Results in other solvents are scanty for metals other than Hg. Liquid Ga and its T1 and In liquid alloys have been studied in DMSO, DMF, NMF, AN,343,894 MeOH360 andEtOH.361 Among solid metals, only Bi,28,152 Au,25,26,109 Al,750,751 and Fe729 have been investigated in a number of nonaqueous solvents. Pt and Pd have been studied in DMSO and... [Pg.175]

The general picture emerging from the pzc in aqueous solutions is that the major variation of <7-0 between two metals is due to with a minor contribution from AX that is governed by metal-solvent interactions. If this is also the case in nonaqueous solvents, a similar picture should be obtained. This is confirmed by Fig. 20 in which the data in DMSO are reported. As in aqueous solution, all points lie to the left of the point of Hg. Bi, In(Ga), and Tl(Ga) lie with Hg on a common line deviating from the unit slope. As in aqueous solution, Ga is further apart. Au is in the same position, relatively close to the Hg line. Finally, the point of Pt is (tentatively) much farther than all the other metals. [Pg.175]

Almost all that is known about the crystal face specificity of double-layer parameters has been obtained from studies with metal single-crystal faces in aqueous solutions. Studies in nonaqueous solvents would be welcome to obtain a better understanding of the influence of the crystallographic structure of metal surfaces on the orientation of solvent molecules at the interface in relation to their molecular properties. [Pg.192]

Intercalation from solutions in nonaqueous solvents (S21). This method may suffer from the drawback that final stoichiometries may not correspond to equilibrium conditions, because of partial leaching out of metal halide. For this reason, some chlorides can be intercalated only from solvents in which they have limited solubility iLS). It has often been the practice to wash intercalates with solvents to remove the excess of intercalant this may lead to stoichiometries lower than the original ones. The two-ampoule method may, therefore, be preferable (H24). [Pg.301]

Intercalation of Metal Chlorides from Nonaqueous Solvents... [Pg.306]

Trivino GC, Klabunde KJ, Dale EB (1987) Living colloidal palladium in nonaqueous solvents. Formation, stability, and film-forming properties. Clustering of metal atoms in organic media. 14. Langmuir 3 986-992... [Pg.167]

In fact, the orientation of water at the potential of zero charge is expected to depend approximately linearly on the electronegativity of the metal.9 This orientation (see below) may be deduced from analysis of the variation of the potential drop across the interface with surface charge for different metals and electrolytes. Such analysis leads to the establishment of a hydrophilicity scale of the metals ( solvophilicity for nonaqueous solvents) which expresses the relative strengths of metal-solvent interaction, as well as the relative reactivities of the different metals to oxygen.23... [Pg.7]

More recently, Ikeda et a/.108 have examined C02 reduction in aqueous and nonaqueous solvents using metal-deposited p-GaP and p-InP electrodes under illumination. Metal coatings on these semiconductor electrodes gave much improved faradaic efficiencies for C02 reduction. In an aqueous solution, the products obtained were formic acid and CO with hydrogen evolution at Pb-, Zn-, and In-coated electrodes, while in a nonaqueous PC solution, CO was obtained with faradaic efficiencies of ca. 90% at In-, Zn-, and Au-coated p-GaP and p-InP, and a Pb coating on a p-GaP electrode gave oxalate as the main product with a faradaic efficiency of ca. 50% at -1.2 V versus Ag/AgCl. [Pg.361]

In contrast, electrocatalysis in a nonaqueous solvent like dichloromethane with soluble palla-dium(II) and silver(II) porphyrins produces mainly oxalate.145 However, demetallation rapidly deactivates the catalysts. In these cases the catalytic processes are interpreted in terms of reduced forms of the macrocyclic ligand, rather than by formation of Pd1 or Ag1 species following metal-centered reduction. [Pg.483]

For some elements, there are a variety of possible precursors, sulfur for instance (Figure 11). Use of metal-organic precursors, used in MOMBE or MOVPE, are possible if they are soluble in water, or a nonaqueous solvent is used. Mixed aqueous-organic solvents could improve solubility. Overall, there would be an increased probability of carbon contamination, however. One of the benefits of using inorganic salts in aqueous solutions is that the number of constituents is limited, and thus the... [Pg.25]

Relatively little attention has been devoted to the direct electrodeposition of transition metal-aluminum alloys in spite of the fact that isothermal electrodeposition leads to coatings with very uniform composition and structure and that the deposition current gives a direct measure of the deposition rate. Unfortunately, neither aluminum nor its alloys can be electrodeposited from aqueous solutions because hydrogen is evolved before aluminum is plated. Thus, it is necessary to employ nonaqueous solvents (both molecular and ionic) for this purpose. Among the solvents that have been used successfully to electrodeposit aluminum and its transition metal alloys are the chloroaluminate molten salts, which consist of inorganic or organic chloride salts combined with anhydrous aluminum chloride. An introduction to the chemical, electrochemical, and physical properties of the most commonly used chloroaluminate melts is given below. [Pg.277]

Sulfuric acid undergoes many other reactions with metals as well as with metal oxides, carbonates, nitrates, sulfides, and so on. It is a versatile nonaqueous solvent. [Pg.349]

Coordination compounds have been produced by a variety of techniques for at least two centuries. Zeise s salt, K[Pt(C2H4)Cl3], dates from the early 1800s, and Werner s classic syntheses of cobalt complexes were described over a century ago. Synthetic techniques used to prepare coordination compounds range from simply mixing the reactants to employing nonaqueous solvent chemistry. In this section, a brief overview of some types of general synthetic procedures will be presented. In Chapter 21, a survey of the organometallic chemistry of transition metals will be presented, and additional preparative methods for complexes of that type will be described there. [Pg.695]

Reaction of a Metal Halide with an Alkene in a Nonaqueous Solvent... [Pg.760]

Table IV is an attempt to summarize the results of these proton transfer studies in nonaqueous solvents. There is no systematic trend in what seems to be the rate limiting step in contrast to the attractive Eigen-Wilkins generalization for the mechanism of metal ion complexation. Obviously, many more proton transfer kinetic studies in nonaqueous solutions are needed for beautiful generalizations to emerge. Whether investigators will have the patience to carry them out or not is the only uncertainty. Table IV is an attempt to summarize the results of these proton transfer studies in nonaqueous solvents. There is no systematic trend in what seems to be the rate limiting step in contrast to the attractive Eigen-Wilkins generalization for the mechanism of metal ion complexation. Obviously, many more proton transfer kinetic studies in nonaqueous solutions are needed for beautiful generalizations to emerge. Whether investigators will have the patience to carry them out or not is the only uncertainty.
MII(bpy )3] is observed (30,31) via cyclic voltammetry in nonaqueous solvents as three 170 mV-separated peaks at -1.2 to -1.3 V vs SCE. The reducibility of the ligand depends on the metal charge and E1/2 for the metal-bound bpy/bpy" couple shifts to less negative potentials as the metal-center charge increases. Thus the first reduction of Ir(bpy)3 +, which occurs at -0.83 V vs SCE in acetonitrile, though 400 mV positive of the MII(bpy)3 +/[MII(bpy)2(bpy )]+ potential, is ascribed to ligand, rather than metal, reduction (41). The... [Pg.388]

In any study of electrosorption of neutral molecules on metallic electrodes, the ions of supporting electrolytes should not be specifically adsorbed. Nevertheless, the interaction of the electrolyte ions with the electrode surface may depend on the interaction of the ions with the solvent. Usually, the stronger the ion-solvent interaction, the weaker the adsorption of the ion. Since the ions are more weakly solvated in nonaqueous solvents than in water, the ions that are not adsorbed from aqueous solutions may still be adsorbed from organic solvents. However, even in the absence of... [Pg.54]

Various processes separate rare earths from other metal salts. These processes also separate rare earths into specific subgroups. The methods are based on fractional precipitation, selective extraction by nonaqueous solvents, or selective ion exchange. Separation of individual rare earths is the most important step in recovery. Separation may be achieved by ion exchange and solvent extraction techniques. Also, ytterbium may be separated from a mixture of heavy rare earths by reduction with sodium amalgam. In this method, a buffered acidic solution of trivalent heavy rare earths is treated with molten sodium mercury alloy. Ybs+ is reduced and dissolved in the molten alloy. The alloy is treated with hydrochloric acid, after which ytterbium is extracted into the solution. The metal is precipitated as oxalate from solution. [Pg.975]


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See also in sourсe #XX -- [ Pg.545 ]




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Metal solutions in nonaqueous solvents optical spectra

Nonaqueous

Nonaqueous solvents

Solvent nonaqueous solvents

With metal halides from nonaqueous solvents

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