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Halide ions transition

The solid anhydrous halides of some of the transition metals are often intermediate in character between ionic and covalent their structures are complicated by (a) the tendency of the central metal ion to coordinate the halide ions around it, to form an essentially covalent complex, (b) the tendency of halide ions to bridge, or link, two metal ions, again tending to covalency (cf. aluminium chloride, p. 153 and iron(III) chloride, p. 394). [Pg.344]

Carbon is partially bonded to both the incoming nucleophile and the departing halide at the transition state Progress is made toward the transition state as the nucleophile begins to share a pair of its electrons with carbon and the halide ion leaves taking with it the pair of electrons m its bond to carbon... [Pg.331]

Among the cases in which this type of kinetics have been observed are the addition of hydrogen chloride to 2-methyl-1-butene, 2-methyl-2-butene, 1-mefliylcyclopentene, and cyclohexene. The addition of hydrogen bromide to cyclopentene also follows a third-order rate expression. The transition state associated with the third-order rate expression involves proton transfer to the alkene from one hydrogen halide molecule and capture of the halide ion from the second ... [Pg.354]

This study suggests a radically new explanation for the nature of Lewis acid activation in the Simmons-Smith cyclopropanation. The five-centered migration of the halide ion from the chloromethylzinc group to zinc chloride as shown in TS2 and TS4 has never been considered in the discussion of a mechanism for this reaction. It remains to be seen if some experimental support can be found for this unconventional hypothesis. The small energy differences between all these competing transition states demand caution in declaring any concrete conclusions. [Pg.145]

As well as viscosity, other factors to be aware of include the purity of the ionic liquids. The presence of residual halide ions in neutral ionic liquids can poison transition metal catalysts, while different levels of proton impurities in chloroalumi-... [Pg.332]

Persulfate (41) reacts with transition metal ions (e.g. Ag, Fe21, Ti31) according to Scheme 3.42. Various other reduetants have been described. These include halide ions, thiols (e.g. 2-mercaptoethanol, thioglycolic acid, cysteine, thiourea), bisulfite, thiosulfate, amines (triethanolamine, tetramethylethylenediamine, hydrazine hydrate), ascorbic acid, and solvated electrons (e.g. in radiolysis). The mechanisms and the initiating species produced have not been fully elucidated for... [Pg.95]

The nucleophile OH uses its lone pair electrons to attack the alkyl halide carbon 180° away from the departing halogen. This leads to a transition state with a partially formed C-O bond and a partially broken C-X bond. The stereochemistry is inverted as the C-O bond fully forms, and the halide ion departs with the electron pair from the former C-X bond. [Pg.22]

It is the only example of a free, persistent phosphirenylium ion, and also, only one stable transition-metal complex of this species was published [78,79]. Quantum chemical calculations [80,81] indicated that in the halogeno-phosphirenes the P-X bonds already possesses a high ionic character and can be described as interactions between phosphirenylium and halide ions. The aromatic character of the phosphirenylium ion was shown to be based on a three-centre two-electron bond of 7i-type and the resonance energy was assessed by calculation to 38 kcal/mol. Before the generation of 32, substituted phosphirenylium ions were... [Pg.89]

Solvation stabilizes the transition state leading to the intermediate carbocation and halide ion more it does the reactants => the free energy of activation is lower. [Pg.259]

Among the potential impurities in ionic liquids water, halide ions and organic starting material are of great importance for transition metal chemistry while the colour of an ionic liquid is not a critical parameter in most applications. [Pg.211]

It is worthwhile to emphasize that the intermediate Hamiltonian Hc(ij) defines a geometry that can be used to construct a model of an activated complex. A portrait of it can be obtained at the BO level of theory. For thermally activativated processes, the transition state is the analogous of the intermediate Hamiltonian, while for processes without thermal activation (a number of reactions taking place in gas phase, such as for example, the SN2 reaction between methyl halides and halides ions [168-171] ) the quantum states of this Hamiltonian mediate the chemical interconversion. For particular... [Pg.320]

Palladium(II) is one of the most important transition metals in catalytic oxidations of allenes [1], Scheme 17.1 shows the most common reactions. Transformations involving oxidative addition of palladium(O) to aryl and vinyl halides do not afford an oxidized product and are discussed in previous chapters. The mechanistically very similar reactions, initiated by nucleophilic attack by bromide ion on a (jt-allene)pal-ladium(II) complex, do afford products with higher oxidation state and are discussed below. These reactions proceed via a fairly stable (jt-allyl)palladium intermediate. Mechanistically, the reaction involves three discrete steps (1) generation of the jt-allyl complex from allene, halide ion and palladium(II) [2] (2) occasional isomeriza-... [Pg.973]

Fig. 10 The secondary a-deuterium KIE for the identity SN2 reactions between halide ions and methyl halides versus the elongation of the C—X bond on going from the reactant to the transition state. Data from Glad and Jensen (1997), modified, with... Fig. 10 The secondary a-deuterium KIE for the identity SN2 reactions between halide ions and methyl halides versus the elongation of the C—X bond on going from the reactant to the transition state. Data from Glad and Jensen (1997), modified, with...
Zinc, cadmium and mercury are at the end of the transition series and have electron configurations ndw(n + l)s2 with filled d shells. They do not form any compound in which the d shell is other than full (unlike the metals Cu, Ag and Au of the preceding group) these metals therefore do not show the variable valence which is one of the characteristics of the transition metals. In this respect these metals are regarded as non-transition elements. They show, however, some resemblance to the d-metals for instance in their ability to form complexes (with NH3, amines, cyanide, halide ions, etc.). [Pg.471]

However, the dependence found experimentally shows this transition is usually gradual when the analyte contains two different types of halide ions. [Pg.54]

Innocenti et al. have studied the kinetics [101] of two-dimensional phase transitions of sulfide and halide ions, as well as electrosorption valency [102] of these ions adsorbed on Ag(lll). The electrode potential was stepped up from the value negative enough to exclude anionic adsorption to the potential range providing stability of either the first or the second, more compressed, ordered overlayer of the anions. The kinetic behavior was interpreted in terms of a model that accounts for diffusion-controlled random adsorption of the anions, followed by the progressive polynucleation and growth. [Pg.925]

See other pages where Halide ions transition is mentioned: [Pg.346]    [Pg.346]    [Pg.204]    [Pg.18]    [Pg.364]    [Pg.104]    [Pg.397]    [Pg.142]    [Pg.362]    [Pg.237]    [Pg.206]    [Pg.45]    [Pg.39]    [Pg.174]    [Pg.149]    [Pg.8]    [Pg.625]    [Pg.250]    [Pg.1390]    [Pg.252]    [Pg.22]    [Pg.649]    [Pg.91]    [Pg.289]    [Pg.55]    [Pg.181]    [Pg.18]    [Pg.365]    [Pg.366]    [Pg.398]    [Pg.131]   
See also in sourсe #XX -- [ Pg.266 ]



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