Electrochemical Kinetics of Cyanometalate Complexes in Aqueous Solution at High Pressures

Abstract: For the aqueous couples Os(CN)(6)(3-/4-), Mo(CN)(8)(3-/4-), and W(CN)(8)(3-/4-), volumes of reaction DeltaV(Ag/AgCl) relative to Ag/AgCl/4.0 mol L(-)(1) KCl and volumes of activation DeltaV(el)() for the electrode reactions are reported. Values of DeltaV(Ag/AgCl) are consistent with a very small increase in the metal-carbon bond length on reduction in each case, the main component of DeltaV(Ag/AgCl) (other than that of the reference electrode) being electrostrictive solvation change. For media in which the cat… Show more

“…Furthermore, for aqueous systems, DV el ‡ is found (1)(2)(3)(4)(5) to be one-half of DV ex ‡ : [1] DV el ‡ = (0.50 ± 0.02)DV ex ‡ which is consistent with the corresponding relationship proposed theoretically by Marcus (6) for the free energies of activation [2] DG el ‡ = DG ex ‡ /2…”

“…in aqueous solution at 25°C, the volumes of activation DV ex ‡ and DV el ‡ (DV ‡ = -RT( ¶ ln k/ ¶P) T , where k is the corresponding rate constant) for the homogeneous self-exchange reaction and the equivalent electrode process respectively have invariably been found to be negative (1)(2)(3)(4)(5). Furthermore, for aqueous systems, DV el ‡ is found (1)(2)(3)(4)(5) to be one-half of DV ex ‡ : [1] DV el ‡ = (0.50 ± 0.02)DV ex ‡ which is consistent with the corresponding relationship proposed theoretically by Marcus (6) for the free energies of activation [2] DG el ‡ = DG ex ‡ /2…”

“…As an "exception that proves the rule," DV ex ‡ and DV el ‡ for electron transfer in water can be positive where the reaction is not of the simple, bimolecular, outer-sphere type -for example, the self-exchange pathway for anionic cyanometalate couples that is mediated by alkali-metal cations (7,8) -but even in such cases eq. [1] still holds with remarkable accuracy.…”

“…[1] as such seems not to apply to nonaqueous systems. On the other hand, DV el ‡ for the nonaqueous systems does correlate loosely with the volume of activation DV diff ‡ for diffusion of the reactants in the particular solvent, and DV diff ‡ can be identified, through the Stokes-Einstein relation [3] D = k B T/6 p h r eff (in which D is the diffusion coefficient of a solute molecule of effective radius r eff in a solvent of viscosity h), with the volume of activation DV visc ‡ for viscous flow of the solvent. The implication is that the electrode reactions in nonaqueous media are either diffusion-controlled (which is highly unlikely, as the rates are generally too low and dependent on the particular system) or controlled by solvent dynamics (solvent "friction").…”

Volumes of activation for electrode processes of various charge-types in nonaqueous solvents

“…Furthermore, for aqueous systems, DV el ‡ is found (1)(2)(3)(4)(5) to be one-half of DV ex ‡ : [1] DV el ‡ = (0.50 ± 0.02)DV ex ‡ which is consistent with the corresponding relationship proposed theoretically by Marcus (6) for the free energies of activation [2] DG el ‡ = DG ex ‡ /2…”

“…in aqueous solution at 25°C, the volumes of activation DV ex ‡ and DV el ‡ (DV ‡ = -RT( ¶ ln k/ ¶P) T , where k is the corresponding rate constant) for the homogeneous self-exchange reaction and the equivalent electrode process respectively have invariably been found to be negative (1)(2)(3)(4)(5). Furthermore, for aqueous systems, DV el ‡ is found (1)(2)(3)(4)(5) to be one-half of DV ex ‡ : [1] DV el ‡ = (0.50 ± 0.02)DV ex ‡ which is consistent with the corresponding relationship proposed theoretically by Marcus (6) for the free energies of activation [2] DG el ‡ = DG ex ‡ /2…”

“…As an "exception that proves the rule," DV ex ‡ and DV el ‡ for electron transfer in water can be positive where the reaction is not of the simple, bimolecular, outer-sphere type -for example, the self-exchange pathway for anionic cyanometalate couples that is mediated by alkali-metal cations (7,8) -but even in such cases eq. [1] still holds with remarkable accuracy.…”

“…[1] as such seems not to apply to nonaqueous systems. On the other hand, DV el ‡ for the nonaqueous systems does correlate loosely with the volume of activation DV diff ‡ for diffusion of the reactants in the particular solvent, and DV diff ‡ can be identified, through the Stokes-Einstein relation [3] D = k B T/6 p h r eff (in which D is the diffusion coefficient of a solute molecule of effective radius r eff in a solvent of viscosity h), with the volume of activation DV visc ‡ for viscous flow of the solvent. The implication is that the electrode reactions in nonaqueous media are either diffusion-controlled (which is highly unlikely, as the rates are generally too low and dependent on the particular system) or controlled by solvent dynamics (solvent "friction").…”

Volumes of activation for electrode processes of various charge-types in nonaqueous solvents

“…On the basis of other measurements and estimates of outer-sphere metal complex preassociations, the small value of the former parameter was not unexpected. 288,289 In a procedure leading to construction of a volume profile, an estimate of þ 30 cm 3 /mol was made for the reaction volume. This total arose from contributions of þ 5, þ 12, and þ 13 cm 3 /mol from the cyt c II/III couple, from the electrostrictive change from the charge change on the Cu center, and from the loss of a water molecule, respectively.…”

Application of High Pressure in the Elucidation of Inorganic and Bioinorganic Reaction Mechanisms

Insights into Solution Chemistry from High Pressure Electrochemistry