The standard cell potential of:
`Zn(s) abs( Zn^(2+) (aq) )abs( Cu^(2+) (aq)) Cu (s)` cell is `1.10` V The maximum work obtained by this cell will be

E.M.F. of Ni(s) | Ni^(2+) (aq)||Cu^(2+) (aq)| Cu(s) cell can be increased by

E^(@) for the cell Zn(s)|Zn^(2+)(aq)|Cu^(2+)(aq)|Cu(s) is 1.1V at 25^(@)C the equilibrium constant for the cell reaction is about

E^(@) for the electrochemical cell Zn(s)|Zn^(2+) 1 M (Aq.)||Cu^(2+) 1 M (aq.)|Cu(s) is 1.10 V at 25^(@)C . The equilibrium constant for the cell reaction, Zn(s) +Cu^(2+) (aq.) hArr Zn^(2+) (aq.)+Cu(s) Will be :

Zn(s) + Cu^(2+)(aq) rarr Zn^(2+)(aq) + Cu(s) The cell representation for the above redox reaction is

The emf of the cell reaction Zn(s) +Cu^(2+) (aq) rarr Zn^(2+) (aQ) +Cu(s) is 1.1V . Calculate the free enegry change for the reaction. If the enthalpy of the reaction is -216.7 kJ mol^(-1) , calculate the entropy change for the reaction.

For the cell, Zn(s)abs(Zn^(2+))abs(Cu^(2+))Cu(s) , the standard cell voltage, E^(0)""_(cell) is 1.10 V. When a cell using these reagents was prepared in the lab, the measured cell voltage was 0.98 One possible explanation for the observed voltage is :

Calculate the standard free enegry change for the reaction: Zn + Cu^(2+)(aq) rarr Cu+Zn^(2+) (aq), E^(Theta) = 1.20V

For the galvanic cell Zn(s)abs(Zn^(2+) ) abs(Cd^(2+)) Cd(s),E_(cell ) = 0.30 V and E_(cell)^(o) = 0.36 V, then value of [Cd^(2+)]//[Zn^(2+)] will be:

The standard reducution potentials of Zn^(2+)|Zn,Cu^(2+)|Cu and Ag^(+)|Ag are respectively -0.76,0.34 and 0.8V . The following cells were constructed. Zn|Zn^(2+)"||"Cu^(2+)|Cu Zn|Zn^(2+)"||"Ag^(+)|Ag Cu|Cu^(2+)"||"Ag^(+)|Ag What is the correct order E_("cell")^(0) of these cell?

The electrode potentials for Cu^(2+) (aq) +e^(-) rarr Cu^+ (aq) and Cu^+ (aq) + e^(-) rarr Cu (s) are + 0.15 V and +0. 50 V repectively. The value of E_(Cu^(2+)//Cu)^@ will be.