The standard electrode potential `E^(@)` and its temperature coefficient `((dE^(@))/(dT))` for a cell are 2V and `-5xx10^(-4) Vk^(-1)` at 300K respectively . The cell reaction is ` Zn(s)+ Cu^(2) (aq)+ Cu(S)` .
The standard reaction enthalpy `Delta_(r) H^(@)` at 300 K `KJmol^(-1)` is :
`([use R = 8 JK^(-1)mol^(-1)` and `F = 96000Cmol^(-1)])`

The standard electrode potential E^(Theta) and its temperature coefficent ((dE^Theta)/(d T)) for a cell are 2V and -5xx10^(-4)VK^(-1) at 300 K respectively. The cell reaction is Zn(s)+Cu^(2+)(aq)to Zn^(2+)(aq) +Cu(s) . The standard reaction enthalpy (Delta_(t)H^(Theta)) at 300 K is 4.12 xx10^(x) J//"mol" . Numerical value of x is _________________ [Use R=8JK^(-1)mol^(-1) and F=96,000 C "mol"^(-1) ].

The temperature coefficient of a given cell , ((delE)/(delT))_P is 1.5xx10^(-4) VK^(-1) at 300 K. The change in entropy of cell during the cource of reaction, Pb((s))+ HgCl_(2)((aq))rightarrowPbCl_(2) (aq)+ Hg(1)

If the standard electrode potential for a cell is at 300 K, the equilibrium constant (K) for the reaction Zn(s) + Cu^(2+) (aq) at 300 k is approximately : (R=8JK^(-1) mol^(-1) , F= 96000 mol^(-1))

The standard reduction potential E^(@) , for the half reaction are : {:(Zn rarr Zn^(2+) + 2e^(-),,,E^(@) = 0.76 V),(Cu rarr Cu^(2+) + 2e^(-),,,E^(@) = 0.34 V):} The emf for the cell reaction, Zn(s)+Cu^(2+) rarr Zn^(2+) + Cu(s) is :

If the equilibrium constant for a reaction is 10, then the value of triangleG^(@) will be: ("Given: "R= 8JK^(-1) mol^(-1) T=300K)

If the standed electrode potential for a cell is 2 V at 300 K, the equilibrium constant (K) for the reaction Zn(s)+Cu^(2+)(aq) hArrZn^(2+)(aq)+Cu(s) at 300 K is approximately (R=8JK^(-1)mol^(-1),F=96000Cmol^(-1))

The cell reaction of a cell is Mg(s)+Cu^(2+)(aq)rarrCu(s)+Mg^(2+)(aq) if the standard reduction potential of Mg and Cu are -2.37 V and +0.34 V respectively The emf of the cell is