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Neutralizing reactant

This fomuila does not include the charge-dipole interaction between reactants A and B. The correlation between measured rate constants in different solvents and their dielectric parameters in general is of a similar quality as illustrated for neutral reactants. This is not, however, due to the approximate nature of the Bom model itself which, in spite of its simplicity, leads to remarkably accurate values of ion solvation energies, if the ionic radii can be reliably estimated [15],... [Pg.837]

Ion/neutral reaction. Interaction of a charged species with a neutral reactant to produce either chemically different species or changes in the internal energy of one or both of the reactants. [Pg.444]

The kinetics of reactions cataly2ed by very strong acids are often compHcated. The exact nature of the proton donor species is often not known, and typically the rate of the catalytic reaction does not have a simple dependence on the total concentration of the acid. However, sometimes there is a simple dependence of the catalytic reaction rate on some empirical measure of the acid strength of the solution, such as the Hammett acidity function Hq, which is a measure of the tendency of the solution to donate a proton to a neutral base. Sometimes the rate is proportional to (—log/ig)- Such a dependence may be expected when the slow step in the catalytic cycle is the donation of a proton by the solution to a neutral reactant, ie, base but it is not easy to predict when such a dependence may be found. [Pg.163]

The ionization mechanism for nucleophilic substitution proceeds by rate-determining heterolytic dissociation of the reactant to a tricoordinate carbocation (also sometimes referred to as a carbonium ion or carbenium ion f and the leaving group. This dissociation is followed by rapid combination of the highly electrophilic carbocation with a Lewis base (nucleophile) present in the medium. A two-dimensional potential energy diagram representing this process for a neutral reactant and anionic nucleophile is shown in Fig. [Pg.264]

Why do free-radical reactions involving neutral reactants and intermediates respond to substituent changes that modify electron distribution One explanation has been based on the idea that there would be some polar character in the transition state because of the electronegativity differences of the reacting atoms ... [Pg.700]

AC is interpreted as the difference in heat capacities between the transition state and the reactants, and it may be a valuable mechanistic tool. Most reported ACp values are for reactions of neutral reactants to products, as in solvolysis reactions of neutral esters or aliphatic halides. " Because of the slight curvature seen in the Arrhenius plots, as exemplified by Fig. 6-2, the interpretation, and even the existence, of AC is a matter of debate. The subject is rather specialized, so we will not explore it deeply, but will outline methods for the estimation of ACp. [Pg.251]

If two neutral reactant molecules yield a polar product, then presumably the transition state will be intermediate in polarity, and we anticipate an increase in rate as the solvent polarity is increased. A quantitative formulation of this case is based on Kirkwood s expression for the free energy of transfer of a dipole of... [Pg.405]

The neutral reactants possess permanent dipoles, the product is ionic, and the transition state must be intermediate in its charge separation, so an increase in solvent polarity should increase the rate. Except for selective solvation effects of the type cited in the preceding section, this qualitative prediction is correct. [Pg.407]

These reactions proceed via a collision between the reactants, with the nucleophilic species attacking the opposite side of the molecule with respect to the ionic substituent that it liberates. Such a process yields a transition structure in which the ion and neutral reactants are weakly bound. [Pg.208]

Since the experiments only involve interchanging the ionic and neutral reactants, it is plausible to consider that a similar reaction complex is involved in the respective H, H and H2, H2 transfer reactions. [Pg.133]

If at any point x (Figure 2) away from the cathode but within the dark space 8N(E,X) denotes the number of ions per unit volume with energy between E and E + dE, such that E > E0, the threshold energy for the reaction, then as the ions move toward the cathode, the total amount of a bimolecular reaction they will undergo with neutral reactant species of density p, to yield Ns secondary ions per cc. at the cathode is given by ... [Pg.326]

The results here clearly demonstrate some of the important differences between reactions in the vapor phase and those in the aqueous phase. Water solvates the ions that form and thus enhances the heterolytic bond activation processes. This leads to more significant stabilization of the charged transition and product states over the neutral reactant state. The changes that result in the overall energies and the activation barriers of particular elementary steps can also act to alter the reaction selectivity and change the mechanism. [Pg.115]

The solvent dependence of the reaction rate is also consistent with this mechanistic scheme. Comparison of the rate constants for isomerizations of PCMT in chloroform and in nitrobenzene shows a small (ca. 40%) rate enhancement in the latter solvent. Simple electrostatic theory predicts that nucleophilic substitutions in which neutral reactants are converted to ionic products should be accelerated in polar solvents (23), so that a rate increase in nitrobenzene is to be expected. In fact, this effect is often very small (24). For example, Parker and co-workers (25) report that the S 2 reaction of methyl bromide and dimethyl sulfide is accelerated by only 50% on changing the solvent from 88% (w/w) methanol-water to N,N-dimethylacetamide (DMAc) at low ionic strength this is a far greater change in solvent properties than that investigated in the present work. Thus a small, positive dependence of reaction rate on solvent polarity is implicit in the sulfonium ion mechanism. [Pg.69]

Herbst and Dunbar" have investigated the effects of exit channel barriers on association reactions of type 43 and have shown that, depending on the size of the barrier, the efficiency of radiative association reactions as a function of N can be strongly curtailed. For example, at 10 K and a nonpolar neutral reactant, they found for a system with a well depth of 2 eV and an exothermic channel barrier of 1.0 eV, N = 130 atoms for 100% sticking efficiency, approximately 10 times the corresponding value of N in the absence of a competitive exothermic channel. [Pg.27]

The ions or cluster ions are thermalized by collisions with an inert carrier gas (usually helium), although often argon or even nitrogen is employed. Neutral reactant gas is added through a reactant gas inlet at an appropriate location downstream in the flow tube, and allowed to react with the injected ions. Rate coefficients, k, are determined by establishing pseudo-first-order reaction conditions in which the reactant ion concentration is small compared to the reactant neutral concentration. Bimolecular rate coefficients, k, are obtained from the slope of the natural logarithm of the measured signal intensity, /, of the reactant ion versus the flow rate (2b of reactant gas 45,48-50... [Pg.188]

The apparatus and techniques of ion cyclotron resonance spectroscopy have been described in detail elsewhere. Ions are formed, either by electron impact from a volatile precursor, or by laser evaporation and ionization of a solid metal target (14), and allowed to interact with neutral reactants. Freiser and co-workers have refined this experimental methodology with the use of elegant collision induced dissociation experiments for reactant preparation and the selective introduction of neutral reactants using pulsed gas valves (15). Irradiation of the ions with either lasers or conventional light sources during selected portions of the trapped ion cycle makes it possible to study ion photochemical processes... [Pg.17]

Bimolecular Reactions between Neutral Reactants Leading to Charged Products... [Pg.72]

Following isolation and thermalization of the desired reactant ion, this species is trapped in the FTICR cell in the presence of the neutral reactant for a period of time sufficient to allow between 10% and 20% conversion to products to take place. If the product ions are each subsequently unreactive toward the neutral reagent, longer reaction times might be employed. [Pg.65]

Secondly, as illustrated in Table 1, the eneigy gained by solvation for ions is so great that a gas phase ion will accept essentially any species as a solvent, including the neutral molecule with which it is reacting. When an ion approaches a neutral reactant, an ion-miolecule complex is formed. This is typically about 7 to 35 kcal/mol more stable than the reactants. For any activation barrier to rise above the eneigy of the reactants (i.e., for the reaction to have a positive it must be... [Pg.198]

See other pages where Neutralizing reactant is mentioned: [Pg.116]    [Pg.130]    [Pg.309]    [Pg.94]    [Pg.118]    [Pg.122]    [Pg.275]    [Pg.116]    [Pg.183]    [Pg.27]    [Pg.27]    [Pg.42]    [Pg.92]    [Pg.96]    [Pg.259]    [Pg.17]    [Pg.76]    [Pg.506]    [Pg.118]    [Pg.662]    [Pg.165]    [Pg.27]    [Pg.17]    [Pg.89]    [Pg.334]    [Pg.173]    [Pg.321]    [Pg.27]    [Pg.49]    [Pg.232]   


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