`Zn(s) + Cl_2 (1 atm ) to Zn^(2+) + 2Cl^(-) ` , the `E^(0)` of the cell is 2.12 V . To increase E

For the redox reaction : Zn(s) + Cu^(2+) (0.1M) to Zn^(2+) (1M) + Cu(s) taking place in a cell, E_("cell")^@ is 1.10 volt. E_("cell") for the cell will be

For the cell Zn(s) | Zn^(2+) || Cu^(2+) | Cu(s) , the standard cell voltage E_("cell")^(0) is 1.10 V . When a cell using these reagents was prepared in the lab, the measured cell voltage was 0.97 V . One possible explanaiton of the observed voltage 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

Consider the following electrode processes of a cell, Cl^- rightarrow 1/2 Cl_2 +e^-. [MCl +e^- rightarrow M +Cl^-] . If EMF of the cell is -1.140 V and E^@ value of the cell is -0.55V at 298K, the value of the equilibrium constant of the sparingly soluble salt MCl is in the order of

The standard EMF for the cell reaction , Zn + Cu^(2+) to Cu + Zn^(2+) is 1.1 volt at 25^@ C . The EMF for the cell reaction , when 0.1 M Cu^(2+) and 0.1 M Zn^(2+) solutions are used , at 25^@ C is

For a cell reaction , Cu^(2+) (C_1 , aq) + Zn(s) to Zn^(2+) (C_2 , aq) + Cu(s) of an electro chemical cell , the change in standard free energy , DeltaG^(0) at a given temeprature is

Ag^(+) + e^(-) rarr Ag, E^(0) = + 0.8 V and Zn^(2+) + 2e^(-) rarr Zn, E^(0) = -076 V . Calculate the cell potential for the reaction, 2Ag + Zn^(2+) rarr Zn + 2Ag^(+)

The standard electrode potential of the htwo half cells are given below Ni^(+2) + 2e^(-) to Ni , E^(@) = -0.25 V , Zn^(+2) + 2e^(-) to Zn , E^(0) = -0.77 V The voltage of cell formed by combining the two half cells would be

The emf of the cell in which of the following reaction , Zn_((s)) +Ni^(2+) (0.1 M) to Zn^(2+) (1.0M) + Ni_((s)) occurs is found to 0.5105 V at 298 K . The standard emf of the cell is