`Ag(s) |Ag^+ (aq) (0.01M) || Ag^+ (aq) (0.1M)| Ag(s)`
`E_( Ag(s) // Ag(aq))^@ = 0.80` volt.

The emf of the cell, Ni|Ni^(2+)(1.0M)||Ag^(+)(1.0M)|Ag [E^(@) for Ni^(2+)//Ni =- 0.25 volt, E^(@) for Ag^(+)//Ag = 0.80 volt] is given by : [E^(@) for Ag^(+)//Ag = 0.80 volt]

Calculate the voltage E of the cell Ag(s) AgIO_(3)(s)|Ag^(+) (x,M), HIO_(3) (0.300M)||Zn^(2+) (0.175M)|Zn(s) If K_(SP) = 3.02 xx 10^(-8) for AgIO_(3)(s) and K_(a) = 0.162 for HIO_(3), E^(@) (Zn^(+2)//Zn) =- 0.76 V, E^(@) (Ag//Ag^(+)) =- 0.8V

Calculate the cell potential of a cell having reaction Ag_(2)S +2e^(-) hArr 2Ag +S^(2-) in a solution buffered at pH =3 and which is also saturated with 0.1M H_(2)S. For H_(2)S: K_(1) = 10^(-8) and K_(2) = 1.1 xx 10^(-13), K_(sp) (Ag_(2)S) = 2xx 10^(-49), E_(Ag^(+)//Ag)^(@) =0.8

Voltage of the cell Pt, H_(2) (1atm)|HOCN(1.3 xx 10^(-3)M)||Ag^(+) (0.8M) |Ag(s) is 0.982V . Calculate the K_(a) for HOCN , neglect [H^(+)] because of oxidation of H_(2)(g) Ag^(+) +e^(-) rarr Ag(s) = 0.8V

The emf of the cell, Pt|H_(2)(1atm)|H^(+) (0.1M, 30mL)||Ag^(+) (0.8M)Ag is 0.9V . Calculate the emf when 40mL of 0.05M NaOH is added.