`E^@` of `In^(3+), In^(+) and Cu^(2+)m Cu^(+) are -0.4 V and -0.42 V` respectively, Calculate the equilibrium constant for the reaction. `In^(2+) + Cu^(2+) to In^(3+) + Cu^(+) ` at `25^@C`.

Calculate the equilibrium constant of the reaction : Cu_((s))+2Ag_((aq))^(+)to Cu_((aq))^(2+)+2Ag_((a)) E_((cell))^(Θ)=0.46V

E_("cell")^(@) for the redox reation 2Ag_((aq))^(+)Cu rarr Cu_((aq))^(2+) +2Ag is 0.46V. Calculate the equibilrium constant of the reaction.

E^@ values of Zn^(2+), Zn and Cu^(2+), Cu are respectively -0.76 V and + 0.34 . Calculate the EMF of the cell Zn//Zn^(2+) (0.1M)"//"Cu^(2+)(0.1 M)//Cu .

The cell for which the cell reaction is H_2 + Cu^(2+) to 2H^(+) + Cu is represented as

E_0 values of Zn^(2+), Zn , Mg^(2+), Mg and Cu^(2+), Cu are -0.76 V, -2.36 and 0.34 V respectively. (a) Which metal can be extracted even from its aqueous solutions by electrolysis ? (b) Which metal acts as best reductant ? Write reactions .

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

Calculate the Electrode potential of single electrode. Cu^(2+)(0.01M)//Cu" "(E^(@)= +0.337V)

The E^(@) values for the changes given below are measured against NHE at 27^(@) C Cu^(2+) + e to Cu^(+) , E^(@) = + 0.15 V , Cu^(+) + e to Cu, E^(@) = + 0.50 V , Zn^(2+) + 2e to Zn , E^(@) = - 0.76 V . The temperature coefficient of emf a cell designed as Zn|Zn^(2+) || Cu^(2+) || Cu is - 1.4 xx 10^(-4)v per degree . For a cell reaction in equilibrium DeltaG= 0 and DeltaG^(@) = -2.303 RT log K_(c) . The heat of reaction and entropy changes during the reaction are related by DeltaG = DeltaH - TDeltaS . The equilibrium constant constant for the reaction : Zn + Cu^(2+) iff Zn^(2+) + Cu is