`I_(2)(s) | I^(-) (0.1M)` half cell is connected to a `H^(+)(aq) | H_2("1 bar ") | Pt ` half cell and e.m.f is found to be `0.7714 V `. If ` E_(I_2|I^(-))^(@) = 0.535 V ` , find the pH of `H^(+) | H_2` half - cell .

The half cell reaction for the corrosion are , 2H^(+) + (1)/(2) O_2 + 2e^(-) to H_2O , E^(0) = 1.23 V and Fe^(2+) + 2e^(-) to Fe(s) , E^(0) = -0.44 V . Find the DeltaG^(0) ( in kJ) for the overall reaction

Which of the following statements is correct ? If E_(Cu^(2+)|Cu)^(@) = 0.34 V and E_(Sn^(2+)|Sn)^(@) = -0.136 V , E_(H^(+)|H_2)^(@) = -0.0V

E.M.F of the cell reaction , 2Ag^(+) + Cu to 2Ag + Cu^(2+) is 0.46 V . If E_(Cu^(2+) // Cu)^(0) is | 0.34 V , E_(Ag^(+)//Ag)^(0) is

The standard potential (E^(0)) for the half reaction are as Zn to Zn^(2+) + 2e^(-) , E^(0) = + 0.76 V Fe to Fe^(2+) + 2e^(-) , E^(0) = + 0.41 V . The emf for the cell reaction Fe^(2+) + Zn to Zn^(2+) + Fe is

E^@ of Fe|Fe^(2+) is +0.44V , E^@ of Cu|Cu^(2+) is -0.32V. Then in the cell

E^(0) for the half cell Zn^(2+) // Zn is - 0.76 V . Emf of the cell Zn// Zn^(2+)(1M) // //H^(+)(1M) // H_2 at 1 atm is

Which one is correct among the following give, the half cell emf's E^(0) Cu^(+2)//Cu=0.337V and E_(Cu^(+1)//Cu)^(0) = 0.521 V

Consider the following standard reduction potentials Fe^(3+)(aq) + e^(-) iff Fe^(3+) (aq) , E^(@) = 0.77 V , H_2O_2(aq) + 2e^(-) iff 2OH^(-)(aq) , E^(@) = 0.88 V For the voltaic cell reaction below , calculate the Fe^(2+) concentration ( in M) that would be needed to produce a cell potential equal to 0.16 V at 25^@ C when [OH^(-)] = 0.1 M , [Fe^(3+)] = 0.5 M and [H_2O_2]= 0.35M 2Fe^(2+)(aq) + H_2O_2(aq) iff 2Fe^(3+) (aq) + 2OH^(-) (aq)

The emf of the following cell Mg | Mg^(+2) (0.01 M) || Sn^(+2) (0.1 M) | Sn at 298 K in 'V' is (Given , E_(Mg^(+2)|Mg)^(@) = -2.34 V, E_(Sn^(+2)|Sn)^(@) = - 0.14 V )