For a spontaneous reaction, `DeltaG`, equilibrium constant K and `E_("cell")^(@)` will be respectively

The change in Gibbs free energy of the system along provides a criterion for the spontaneity of a process at constant temperature and pressure. A change in the free energy of a sytem at constant temperature and pressure will be: DeltaG_("system") = DeltaH_("system") - T DeltaS_("system") For a spontaneous reaction DeltaG , equilibrium constant K and E_("cell")^(0) will be respectively:

A change in the free energy of a system at constant temperature and pressure will be: Delta_(sys)G = Delta_(sys)H -T Delta_(sys)S At constant temperature and pressure Delta_(sys) G lt 0 (spontaneous) Delta_(sys)G = 0 (equilibrium) Delta_(sys)G gt 0 (non-spontaneous) For a spontaneous reaction DeltaG , equilibrium K and E_(cell)^(Theta) will be, respectively

At equilibrium, the value of equilibrium constant K is

The equilibrium constant is 10 at 100 K . Hence, DeltaG will be negative.

For a spontaneous reaction Delta G^@ and E^@ cell will be respectively :

For a spontaneous reaction Delta G^@ and E^@ cell will be respectively :

Why is equilibrium constant K related to only E_("cell")^(Theta) and not E_("cell") ?

For a given exothermic reaction , K_P and K_p' are the equilibrium constant at temperature T_1 and T_2 respectively .Assuming that heat of reaction is constant in temperature range between T_1 and T_2 , it is readly observed that

Which is the correct relationship between DeltaG^(@) and equilibrium constant K_(p) ?

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