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Posted:
5 years ago
8 juil. 2019, 13:31 UTC−4
Updated:
5 years ago
8 juil. 2019, 13:30 UTC−4
The electrochemical potential of a charged species is the chemical potential mu + z_iFphi where z_i is the charge number of the species, F the Faraday constant and phi the Galvani potential. This definition comes from Guggenheim and has proved to be very useful. Potential of an electron in the solid phase (electrode) minus phi is the electrode potential, which leads to the Nernst equation. Hence, the electrolyte potential is the potential that appears in the electrochemical potential of a species in the solution. It cannot be measured as such but summing all the Galvani potential differences in an electrochemical cell, the measurable cell potential can be defined.
The electrochemical potential of a charged species is the chemical potential mu + z_i*F*phi where z_i is the charge number of the species, F the Faraday constant and phi the Galvani potential. This definition comes from Guggenheim and has proved to be very useful. Potential of an electron in the solid phase (electrode) minus phi is the electrode potential, which leads to the Nernst equation. Hence, the electrolyte potential is the potential that appears in the electrochemical potential of a species in the solution. It cannot be measured as such but summing all the Galvani potential differences in an electrochemical cell, the measurable cell potential can be defined.