The standard EMF of the cell reaction
`1/2Cu(s)+1/2Cl_2(g) to 1/2Cu^(2+)+Cl^-`
is 0.2 V. The value of `/_\G^0` will be

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

The standard emf for the cell cell reaction Zn + Cu^(2+) rarr Zn^(2+) + Cu is 1.10 volt at 25^@ C . The emf for the cell reaction when 0.1 M Cu^(2+) and 0.1 M ZN^(2+) solutions are used at 25^@ =C is .

The standard potential of the cell reaction Zn+Cl_(2)rarr Zn^(2+)+2Cl^(-) is 2.10V .Then the emf of the cell Zn|Zn^(+2)(0.05M)|Cl^(-)(0.2M)|Cl_(2),Pt would be

The standard e.m.f. of the cell involving the reaction 2Ag^(+) (aq)+H_2(g)→2Ag(s)+2H^(+) (aq), is 0.80 V. The standard oxidation potential of Ag electrode is

Enthalpy change for reaction 1//2H_(2)(g)+1//2Cl_(2)(g)toHCl(g) is called :-

For the reaction, 2Cl(g) rarr Cl_2(g) , the correct option is:

Calculate the equilibrium constant for the following cell reaction. (1)/(2)Cl_(2) (g) +Br^(-) to (1)/(2) Br_(2) (l) +Cl^(-) , E^(Theta) =0.30V

The standard reduction potential for the half-cell reaction, Cl_2 + 2e^(-) to 2Cl^(-) will be (Pt^(2+)+2Cl^(-)to Pt + Cl_2 , E_"cell"^@=-0.15 V , Pt^(2+) + 2e^(-) to Pt, E^@=1.20 V)

The standard cell potential of: Zn(s) abs( Zn^(2+) (aq) )abs( Cu^(2+) (aq)) Cu (s) cell is 1.10 V The maximum work obtained by this cell will be

Calculate the standard free energy change for the following reaction Zn(s) + Cu^(2+)(aq) to Zn^(2+) (aq) + Cu(s) Given : Delta_fG^@ [Cu^(2+)(aq)] = 65.0kJ mol^(-1) Delta_f G^@ [ Zn^(2+) (aq)] = -147.2 kJ mol^(-1)