For a cell reaction involving a two electron change, the standard emf of the cell is found to be 0.295 V at `25^(@)C` the equilibrium constant of the reaction at `25^(@)C` will be:

For a cell reaction involving a two electron change, the standrard emf of the cell is found to be 0.295V" at "25^(@) C. The equilibrium constant of the reaction at 25^(@) C will be:

At 25^(@)C , the standard emf of a cell having reaction involving two electrons change is found to be 0.295 V. The equilibrium constant of the reaction is :

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

The standard emf of a galvanic cell involving cell reaction with n = 2 is found to be 0.295 V at 25^(@)C . The equilibrium constant of the reaction would be (Given F=96,500 C mol^(-1), R = 8.314 JK^(-1) mol^(-1) ):

The standard emf for the cell reaction, 2Cu^(+)(aq)toCu(s)+Cu^(2+)(aq) is 0.36V at 298K . The equilibrium constant of the reaction is

Derive an expression relating standard e.m.f. of the cell with the equilibrium constant of the cell reaction.

The value of equilibrium constant for a feasible cell reaction is :

The standard reduction potential at 25 degree Celsius for the reaction, volt. The equilibrium constant for the reaction : is

For the reduction of silver ions with copper metal, the standard cell potential was found to be +0.46 V at 25^(@) C . The value of standard Gibbs energy, DeltaG^(@) will be (F = 96,500C mol^(-1)) :

For the reduction of silver ions with copper metal, the standard cell potential was foound to be +0.46 V at 25^(@) C . The value of standard Gibbs energy, DeltaG^(@) will be (F = 96,500C mol^(-1)) :