The oxidation electrode potential E, of a `0.1` M solution of `M^(+)` ions `(E_(RP)^(o) = - 2.36 V)` is :

The reduction electrode potential E of 0.1 M solutoin of M^(+) "ions" (E_(RP)^(@)=-2.36 V) is

The single electrode potential E_(M^(+)//M) of 0.1 M solution of M^(+) ions for the half cell M^(+)+e^(-)rarr M(s) with E^(o)=-2.36V is :

Electrolusis involves electronation and de-electronation at the redpective electrodes. Anode of electrolytic cell is the electrode at which de-electronation takes place whereas at cathode electronation is noticed. If two or more ions of same charge are to be electronated or de-electronated, the ion having lesser discharge potential is dischargeed. Discharge potential of an ion refers for E_(OP)^(@) or E_(RP)^(@) as the case may be. The products formed at either electrode is given in terms of Faraday's laws of electrolysis i.e., w = (E.i.t)/(96500) E. 5 litre solution of 0.4 M Ni(NO_(3))_(2) is electrolysed using Pt electrodes with 2.4125 ampere current for 10 hour:

The standard electrode potential (reduction) of Ag^(+)|Ag is 0.800 V at 25^(@)C . Its electrode potential in a solution containing 10^(-3)M ion of Ag^(+) ions is:-

(a) Calculate the potential of Zn^(2+)//Zn electrode in which zinc ion activity is 0.001 M. mol^(-1),=96500 C mol^(-1), E_(Zn^(2+)//Zn)^(@)=-0.76" V ") (b) Calculate the electrode potential of copper electrode dipped in a 0.1 M solution of copper sulphate at 298 K, assuming CuSO_(4) to be completely ionised. The standard reduction potential of copper , E_(Cu^(2+)//Cu)^(@)=0.34" V " at 298 K.