Nuclear magnetic resonance studies of alkali metal anions

Dye, James; Andrews, Charles W.; Ceraso, Joseph M.

doi:10.1021/j100593a058

Cited by 71 publications

(45 citation statements)

References 10 publications

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“…spectra of Na-, Rb-and Cs-have now been reported. 61 The chemical shift of Na-, large and diamagnetic, is the same as that calculated for the gaseous anion and is essentially independent of solvent. The apparent absence of a large paramagnetic shift of Na-upon solvation and the independence of solvent, have been in support of a model in which solvent is excluded from the region occupied by the sodium 2p electrons.…”

Section: Ii)mentioning

confidence: 56%

The Electronic Properties of Metal Solutions

Edwards

1981

Physics and Chemistry of Liquids

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The introduction of sodium metal into anhydrous liquid ammonia produces an intensely coloured blue solution in which localised excess electrons, sodium cations, and various agglomerates of these species co-exist in equilibrium. With increasing metal concentration the system transforms into a bronze metallic conductor. In the transitional range, cooling of the (homogeneous) sample can give rise to a remarkable liquid-liquid separation in which both dilute (blue) and concentrated (bronze) phases co-exist. The apparent experimental simplicity of this system which permits the localisation of the fundamental unit of electrical change in dilute solutrons, and its itineracy in concentrated solutions, has attracted a considerable amount of study from both chemists and physicists during the last 100 years.In this article we discuss the recent advances made not only in the study of metals in liquid ammonia, but also in solutions of metals in various other solvents, for example, amines and ethers. The review attempts to cover the properties of metal solutions in the dilute and concentrated ranges, as well as the nature of the Metal-non-Metal transition in these systems.

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Section: Ii)mentioning

confidence: 56%

The Electronic Properties of Metal Solutions

Edwards

1981

Physics and Chemistry of Liquids

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“…Both of these predictions have been shown to be correct in this case. The solubility of sodium in MA in the presence of either complexing agent is a t least 0.1 M and the integrated intensities of the *3Na NMR absorptions of Na+C222 and Na-are equal within experimental error, 11,12 showing that the relative concentration of esolv-is low.…”

Section: Equilibria Involving M-in Solutionmentioning

confidence: 80%

Strategies for the preparation of compounds of alkali metal anions

Dye¹,

Andrews²,

Mathews³

1975

J. Phys. Chem.

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Publication costs asslsted by the U. S. Energy Research and Development AdmlnlstratlonBy using alkali cation complexing agents of the crown and cryptand classes (C) and appropriate solvents, solutions can be prepared which contain essentially only M+C and M-in equal concentrations. From estimates of the metal solubility in the absence of the complexing agent and of the cation complexation constant, the solubility in the presence of the complexing agent can be predicted. If, in the metal solution with C absent, the esolv-/M-ratio is appreciable, then when C is used and the solution is allowed to contact excess metal, this ratio will remain nearly the same. Therefore, in addition to MC+ and M-, the solution may contain relatively high concentrations of esolv-. Examples of the application of these equilibrium considerations to various metal-solvent combinations are described. Only Na+C.Na-, in which C i s 2,2,2 cryptand has been prepared as a crystalline solid. Gold-colored solid films have been obtained by rapid evaporation of solutions of Na, K, Rb, and Cs in one or more of the solvents methylamine (MA), ethylamine (EA), and tetrahydrofuran (THF) when the complexing agent 2,2,2 cryptand is present. In addition, gold-colored films are obtained with Na and K when 18-crown-6 is used. The former metal gives the film when MA is the solvent while the latter gives it with THF. In these cases, the gold film apparently yields the metal plus 18-crown-6 when the solvent vapors are removed. The criteria for thermodynamic vs. kinetic stability of salts of M-are considered.

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“…Gaseous reaction products were searched for by GC with a 2.4-m stainless steel column packed with Al 2 O 3 , 0.02-0.03 mm, deactivated with 5% K 2 CO 3 in an INCO 505 gas chromatograph equipped with a flame ionization detector. 1 H and 13 C NMR spectra were recorded at 20°C on a Varian VXR-300 multinuclear spectrometer at the 1 H resonance frequency of 300 MHz, and at the 13 C resonance frequency of 75 MHz. Deuterated acetone was used as the solvent.…”

Section: Methodsmentioning

confidence: 99%

“…Mass spectrum (m=e): 134 [M þ , 4]; 116 (7); 105 (11); 91 (100); 77 (7); 65 (30); 51 (9); 39 (11). 1 H and 13 C NMR spectra (in CDCl 3 ) have been already presented in [39,40].…”

Section: Benzyl Vinyl Ether (23)mentioning

confidence: 99%

“…Alkalides, M À , M þ C, are salts containing alkali metal anions and cations complexed by a ligand, e.g., crown ether [1][2][3][4]. They are known as two-electron-transfer species [5], used in the reactions with alkenes [6][7][8][9], alkines [10], alkyl halides [11,12], silyl halides [13], ketones [14,15], esters [16][17][18][19][20], and ethers [12,[20][21][22][23][24][25][26][27][28].…”

Section: Introductionmentioning

confidence: 99%

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