I don't think that's right. I think it will be easier if you try to think physically and apply Le Chatelier's principle.
Standard electrode potentials are defined for the reduction half-reaction. The electrode potential will be increased by any change that tends to push the reaction to the right, e.g. an increase in concentration of the oxidised form or a reduction in concentration of the reduced form.
So E = E° + RT/nF*ln([ox]/[rd]) {Insert exponents as required by stoichiometry, but you get the point I hope}
This applies to both cathode and anode. Then
E
cell = E
c - E
a = E
c° - E
a° + RT/nF*ln([ox]
c[rd]
a/[rd]
c[ox]
a)
= E
cell° - RT/nF*lnQ
where Q is the reaction quotient for the overall reaction ox
c + rd
a rd
c + ox
aThe negative sign is because Q has products on top and reactants on the bottom, so an increase in Q would tend to push the reaction to the left, and so reduce the cell emf.
You are getting confused with your anode potentials. Your statement that E
a=E
a0-R*T/z*F*ln([M
az+]/[M
a]) is correct if E
a° is the potential for the
oxidation, i.e.
minus the standard reduction potential. But then E
cell = E
c + E
a (as so defined). In short, you can regard the overall reaction as the cathodic reduction
plus the anodic oxidation, or as the cathodic reduction
minus the anodic reduction, but
not as the reduction minus the oxidation.
This all looks complicated, but I hope it helps to clarify things a bit. Briefly, I suggest:
(i) Think in terms of reduction half-reactions and potentials, subtract as appropriate (anode from cathode).
(ii) Apply Le Chatelier.