`E_(cell)^@` for the reaction `Co(s)+Ni^(2+) to Co^(2+)+Ni(s)` is +0.03 volt. IF cobalt metal is added to an aqueous solution having `[Ni^(2+)]=1M`,

E_(cell)^@ for the reaction Cu^(2+)+2Cl^(-) to Cu(s)+Cl_2(g) is -1.02 V. This reaction

E_(cell)^@ for Zn(s)+Pb^(2+) (1M ) to Zn^(2+) (1M) +Pb(s) is 0.66 volt. E_(cell) for the reaction Zn(s)+Pb^(2+) (0.1M) to Zn^(2+) (0.1M) +Pb(s) is

The standard E.M.F. for the cell reaction: Zn(s) + Cu^(2+) (aq) - Zn^(2+) (aq) + (Cu) is 1.10 volts at 25^(@) C. The EMF. For the cell reaction when 0.01 M Cu^(2+) and 0.1 M Zn^(2+) solutions are used at 25^(@) C is:

For the cell reaction Zn(s)+Mg^(2+) (1M)=Zn^(2+) (1M) +Mg , the emf has been found to be 1.60V E^@ of the cell is

The measured EMF at 298 K for the cell reaction, Zn(s) + Cu^(2+)(1.0 M) rarr Cu(s) + Zn^(2+)(0.1M) is 1.13 V. Calculate E^(@) for the cell reaction.

For the cell reaction, Mg(s)+2Ag^(+) (aq.) rarr Mg^(2+) (aq) + 2Ag(s) E_(cell)^(@) : +3.17 V at 298 K. The value of E_(cell)^(@) triangle G^(@) and at Ag^(+) and Mg^(2+) concentrations of 0.001 M and 0.02 M respectively are:

E^(@) for the electrochemical cell Zn(s) | Zn^(2+)1M (aq)|| Cu^(2+) 1M(aq)| Cu (s) is 1.10 V at 25^(@) C. The equilibrium constant for the cell reaction, Zn(s)+Cu^(2+) (aq.) rarr Zn^(2+) (aq.) + Cu(s) will be:

Given the following standard electrode potentials : "Element" " " "Electrode reaction" E_((298)^(@) " " ("Volts") Zn//Zn_((aq))^(2+)+2etoZn_((s)) -0.76 Sn//Sn_((aq))^(2+)+2etoSn_((s))-0.14 Pb//Pb_((aq))^(2+)+2etoPb_((s))-0.13 Cu//Cu^(2+)+2etoCu_((s))+0.34 Based on the above data, identify the correct answer. From an aqueous solution of the salts