For the reduction of silver ions with copper metals, the standard cell potential was found to be +0.4V at `25^(@)`C. The value of standard Gibb's energy `DeltaG^(@)` will be `(F=96500 C mol^(-1))` :-

For a cell reaction involving a two-electron change, the standard e.m.f. of the cell is found to be 0.295V at 25^(@)C . The equilibrium constant of the reaction at 25^(@)C will be:

The standard e.m.f. of a cell involving one electron change is found to be 0.591V at 25^(@)C . The equilibrium constant of the reaction is (F = 96,500C mol^(-1) R = 8.314 J K^(-1) mol^(-1))

The solubiltiy product of silver iodide is 8.3 xx 10^(-17) and the standard potential (reduction) of Ag,Ag^(+) electrode is +0.800 volts at 25^(@)C . The standard potential of Ag,AgI//I^(-) electrode (reduction) from these data is

Which of the following represents the reduction potential of silver wire dipped into 0.1M AgNO solution at 25^(@)C :-

Stadard reduction electrode potentials of three metals A,B and C are respectively +0.5V, -3.0V and -1.2V . The reducing powers of these metals are:

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:-