Ion-solvent effects

We can rule out the possibility that the effect is due to the n-butylammonium ions. An electron micrograph of the supernatant fluid, taken under the same freeze-fracture conditions, was completely featureless. This is consistent with the thermodynamic behavior of simple n-butylammonium salt solutions their enthalpy of solution is nearly equal to zero [8] and their partial molar volumes are nearly independent of concentration [9], implying that there are no special ion-solvent effects in the system. The necessary conclusion is that the cooling rate used in our experiments, of the order of 103 K/sec, was too low to prevent a major reorganization of the microstructure. This could have serious repercussions for data taken from electron microscopy studies of biological systems, which are necessarily aqueous macroionic systems. 

Rates of QnFC oxidation of alcohols in H2O-ACOH fall in the order cinnamyl > crotyl > allyl and increase with decreasing dielectric constant. The oxidation of j-PrOH by TPFAC in H2O-ACOH-H2SO4 is of fractional order in H+ ions solvent effects have been analysed using the Taft and Swain multiparametric equation. ... 

The charge density on the alkali metal cations follows the sequence Li > Na > K . As a consequence Li cations are the most strongly hydrated in aqueous solution (as evidenced in Table 2.1) and cations the least as shown in Fig. 2.9. This observation suggests, as is the case, that the deviation from the Debye-Hiickel limiting law and the extended Debye-Hiickel law at higher concentrations is due to ion-solvent effects. 

Caution For ion ic reaction s in solution, solven t effects can play a sign ificari I roic. fhesc, of course, arc neglected in calculation s on a single molecule. You can obtain an indication of solvent effects from sem i-eni pirical calculations by carefully adding water molecules to th e solute m olectile. 

Table 2,8, Solvent effect on the endo-exo selectivity (% endo -% exo) of the nncatalysed and Cu" -ion catalysed Diels-Alder reaction between 2,4c and 2,5 at 25°C.

There is no one best method for describing solvent effects. The choice of method is dependent on the size of the molecule, type of solvent effects being examined, and required accuracy of results. Many of the continuum solvation methods predict solvation energy more accurately for neutral molecules than for ions. The following is a list of preferred methods, with those resulting in the highest accuracy and the least amount of computational effort appearing first ... 

If we consider the effect of nitrous acid upon zeroth-order nitration in organic solvents we must bear in mind that in these circumstances dinitrogen tetroxide is not much ionised, so the measured concentration of nitrous acid gives to a close approximation the concentration of dinitrogen tetroxide. Further, the negligible self-ionisation of nitric acid ensures that the total concentration of nitrate ions is effectively that formed from dinitrogen tetroxide. Consequently as we can see from the equation for the ionisation of dinitrogen tetroxide ( 4.3.1),... 

NITRATIONS WITH NITRONIUM IONS THE GENERAL CASE 6.2.1 Evidence from solvent effects... 

The equation does not take into account such pertubation factors as steric effects, solvent effects, and ion-pair formation. These factors, however, may be neglected when experiments are carried out in the same solvent at the same temperature and concentration for an homogeneous set of substrates. So, for a given ambident nucleophile the rate ratio kj/kj will depend on A and B, which vary with (a) the attacked electrophilic center, (b) the solvent, and (c) the counterpart cationic species of the anion. The important point in this kind of study is to change only one parameter at a time. This simple rule has not always been followed, and little systematic work has been done in this field (12) stiH widely open after the discovery of the role played by single electron transfer mechanism in ambident reactivity (1689). 

Bombardment of a liquid surface by a beam of fast atoms (or fast ions) causes continuous desorption of ions that are characteristic of the liquid. Where the liquid is a solution of a sample substance dissolved in a solvent of low volatility (often referred to as a matrix), both positive and negative ions characteristic of the solvent and the sample itself leave the surface. The choice of whether to examine the positive or the negative ions is effected simply by the sign of an electrical potential applied to an extraction plate held above the surface being bombarded. Usually, few fragment ions are observed, and a sample of mass M in a solvent of mass S will give mostly [M + H] (or [M - H] ) and [S -I- H]+ (or [S - H] ) ions. Therefore, the technique is particularly good for measurement of relative molecular mass. 

In fee absence of fee solvation typical of protic solvents, fee relative nucleophilicity of anions changes. Hard nucleophiles increase in reactivity more than do soft nucleophiles. As a result, fee relative reactivity order changes. In methanol, for example, fee relative reactivity order is N3 > 1 > CN > Br > CP, whereas in DMSO fee order becomes CN > N3 > CP > Br > P. In mefeanol, fee reactivity order is dominated by solvent effects, and fee more weakly solvated N3 and P ions are fee most reactive nucleophiles. The iodide ion is large and very polarizable. The anionic charge on fee azide ion is dispersed by delocalization. When fee effect of solvation is diminished in DMSO, other factors become more important. These include fee strength of fee bond being formed, which would account for fee reversed order of fee halides in fee two series. There is also evidence fiiat S( 2 transition states are better solvated in protic dipolar solvents than in protic solvents. 

It is not difficult to incorporate this result into the general mechanism for hydrogen halide additions. These products are formed as the result of solvent competing with halide ion as the nucleophilic component in the addition. Solvent addition can occur via a concerted mechanism or by capture of a carbocation intermediate. Addition of a halide salt increases the likelihood of capture of a carbocation intermediate by halide ion. The effect of added halide salt can be detected kinetically. For example, the presence of tetramethylammonium... 

The range of nueleophiles whieh have been observed to partieipate in nueleophilie aromatie substitution is similar to that for S[, 2 reactions and includes alkoxides, phenoxides, sulftdes, fluoride ion, and amines. Substitutions by earbanions are somewhat less common. This may be because there are frequently complications resulting from eleetron-transfer proeesses with nitroaromatics. Solvent effects on nucleophilic aromatic substitutions are similar to those discussed for S 2 reactions. Dipolar... 

To go from experimental observations of solvent effects to an understanding of them requires a conceptual basis that, in one approach, is provided by physical models such as theories of molecular structure or of the liquid state. As a very simple example consider the electrostatic potential energy of a system consisting of two ions of charges Za and Zb in a medium of dielectric constant e. 

The dissolving of electrolytes in water is one of the most extreme and most important solvent effects that can be attributed to electric dipoles. Crystalline sodium chloride is quite stable, as shown by its high melting point, yet it dissolves readily in water. To break up the stable crystal arrangement, there must be a strong interaction between water molecules and the ions that are formed in the solution. This interaction can be explained in terms of the dipolar properties of water. 

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