Given that `E_(M^(+)//M)^(@)=-0.44V` and `E_(X^(+)//X)^(@)=-0.33V` at
`298K`. The value of `E_("cell")` for
`M(s)|M^(+)(0.1M)||X^(+)(0.2M)|X(s)` at `298K` will be `[log 2=0.3,log3=0.48,log5=0.7]`

Given E_(Cr^(3+)//Cr)^(@)= 0.72V , E_(Fe^(2+)//Fe)^(@)=-0.42V . The potential for the cell Cr|Cr^(3+)(0.1M)||Fe^(2+) (0.01M) | Fe is :

Given E_(Cr^(3+)//cr)^@ =- 0.72 V, E_(Fe^(2+)//Fe)^@ =- 0.42 V . The potential for the cell Cr | Cr^(3+) (0.1 M) || FE^(2+) (0.01 M) | Fe is .

E_(M^(3+)//(M))^(@) = -0.036V , E_(M^(2+)//M)^(@)= -0.439V . The value of standard electrode potential for the change, M^(3+)(aq) + e^(-)rightarrow M^(2+) (aq) will be :

If E^(@)(M^(+)/M)= -0.44V and E^(@)(X/X^(-)) = 0.33V . From this data one can conclude that:

Given E_(M^(4+),M^(3+))^(0)=xV, E_(M^(4+),M)^(0)="y V hence "E_(M^(3+),M)^(0) , is equal to :

At 2 atm pressure the value of (x)/(m) will be : (log 2 = 0.3010)

Given that (at T = 298 K) Cu(s) | Cu^(2+)(1.0M) || Ag^(+)(1.0M)| Ag(s) underset(E_(cell)^(@) = 0.46V Zn(s) | Zn^(2+) (1.0M) || Cu^(2+) (1.0M) | Cu(s) underset(E_(cell)^(@) = 1.10V Then E_(cell) for, Zn | Zn^(2+)(0.1M) || Ag^(+)(0.1M) | Ag at 298 K will be:

For the electrochemicl cell, M|M^(+)||X^(-)|X E_((M^(+)//M))^(@) = 0.44 V and E_((X//X^(-)))^(@) = 0.33 V From this data one can deduce that :

Calculate EMF of the cell A| A^(+3) (0.1M) || B^(+2) (0.01M) | B Given E^(@) A|A^(+3) = 0.75V E^(@)B | B^(+2) = 0.45V

Calculate the emf of the cell Fe(s)+2H^(+)(1M)toFe^(+2)(0.001M)+H_(2)//(g),1 atm) (Given : E_(Fe^(+2)//Fe)=-0.44V)