The cell , `Zn | Zn^(2+) (1M) || Cu^(2+) (1M) Cu (E_("cell")^@ = 1. 10 V)`,
Was allowed to be completely discharfed at `298 K `. The relative concentration of `2+` to `Cu^(2+) [(Zn^(2=))/(Cu^(2+))]` is :

The cell , Zn | Zn^(2+) (1M) || Cu^(2+) (1M) Cu (E_("cell")^@ = 1. 10 V) , was allowed to be completely discharged at 298 K . The relative concentration of Zn^(2+) to Cu^(2+) [(Zn^(2=))/(Cu^(2+))] is :

The cell , Zn//Zn^(2+) (1M) // Cu^(2+) (1M) // Cu (E_("Cell")^@ = 1.10V) , was allowed to be completely discharged at 298 K. The relative concentration of Zn^(2+) to Cu^(2+) is

The cell Zn | Zn ^(2+) (1M)||Cu ^(2+)(1M)|Cu (E ^(@) _(cell) = 1. 10V) was allowed to be completely discharged at 298 K. The relative concentration of Zn ^(2+) to Cu ^(2+) (([Zn ^(2+)])/([Cu^(2+)])) is :

The cell Zn//Zn^(2+) (1 M) ||Cu^(2+)(1M)//Cu(E_("cell")^(0) = 1.10 V) was allowed to be completely discharged at 298 K. The relative concentration of Zn^(2+) to Cu^(2+) (([Zn^(2+)])/([Cu^(2+)])) is 10^(x) . The value of x is : (take (2.303 RT)/(F) = 0.059 round off your answer up to one decimal)

The cell Zn|Zn^(2+)(1M)||Cu^(2+)(1M)|Cu (E_(cell)^@=1.10V) was allowed to be completely discharged at 298K. The relative concentration of Zn%^(2+) to Cu^(2+)(([Zn^(2+)])/([Cu^(2+)])) is: