Rate constant, dependence, pyridinium

Eqs. 9 and 10 make clear predictions about the dependence of quenching rate constants on the free energy change in the quenching step. One way of testing the theory is to observe the quenching of the excited state by a series of related quenchers where the parameters kq(0), K, and k j) should remain sensibly constant and yet where the potentials of the quenchers as oxidants or re-ductants can be varied systematically. Such experiments have been carried out, most notably with the MLCT excited state, Ru(bpy)3 + (1). The experiments have utilized both a series of oxidative nitroaromatic and alkyl pyridinium quenchers, and a series of reductive quenchers based on aniline derivatives. From the data and known redox potentials for the quenchers, plots of RTlnk q vs. 

The rate constants for the reaction of a pyridinium Ion with cyanide have been measured in both a cationic and nonlonic oil in water microemulsion as a function of water content. There is no effect of added salt on the reaction rate in the cationic system, but a substantial effect of ionic strength on the rate as observed in the nonionic system. Estimates of the ionic strength in the "Stern layer" of the cationic microemulsion have been employed to correct the rate constants in the nonlonic system and calculate effective surface potentials. The ion-exchange (IE) model, which assumes that reaction occurs in the Stern layer and that the nucleophile concentration is determined by an ion-exchange equilibrium with the surfactant counterion, has been applied to the data. The results, although not definitive because of the ionic strength dependence, indicate that the IE model may not provide the best description of this reaction system. 

Following earlier studies of the oxidation of formic and oxalic acids by pyridinium fluoro-, chloro-, and bromo-chromates, Banerji and co-workers have smdied the kinetics of oxidation of these acids by 2, 2Tbipyridinium chlorochromate (BPCC) to C02. The formation constant of the initially formed BPCC-formic acid complex shows little dependence on the solvent, whilst a more variable rate constant for its decomposition to products correlates well with the cation-solvating power. This indicates the formation of an electron-deficient carbon centre in the transition state, possibly due to hydride transfer in an anhydride intermediate HCOO—Cr(=0)(0H)(Cl)—O—bpyH. A cyclic intermediate complex, in which oxalic acid acts as a bidentate ligand, is proposed to account for the unfavourable entropy term observed in the oxidation of this acid. 

Acidity constants and rates of reversible deprotonation of triphenylphosphonium ion (54), (55) and pyridinium ions (56), (57) by amines in water, 50 50 v/v DMSO-water, and 90 10 v/v DMSO-water have been determined.157 The intrinsic rate constants for proton transfer were relatively high for all four carbon acids and showed little solvent dependence. This is in contrast with nitroalkanes, which have much lower intrinsic rate constants and show a strong solvent dependence.158... 

The l-alkyI-2-, 3- and 4-carbamidopyridinyl radicals may be generated in water from the corresponding pyridinium ions by pulse radiolysis or radiolysis. The rate constant for the disappearance of 3 are pH-independent and close to diffusion controlled (Eq. 27). The rate constants for 4 are pH-dependent. Completely protonat 4 reacts with itself at rates somewhat less than diffusion controlled the rate constants decrease linearly with increasing pH (slope ca. 1) (Eq. 28). Rates in the range pH 8-11 could be followed using a pyridinyl ester. A minimum rate was found near pH 9.2 at higher pH values, the hydrolysis of the pyridinyl ester to the carboxylate controlled the rate (Eq. 29), since the pyridinyl carboxylate would react with itself in a diffusion controlled process (Eq. 30). 

Fig. 4. The dependence of intramicellar quenching rate constant on Gibbs energy changes of electron transfer for quenching of ruthenium-tris-4,7-diphenyl-l, 10-phenanthrolin by substituted pyridinium cations in SDS micellar solution [124]...

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