Standared electrode potential of two half-reactions are given below :
`Fe^(2+) iff Fe " "E^(@) = -0.44 V , Fe^(3+) iff Fe^(2+) " "E^(@) = + 0.77V `
If `Fe^(2+) , Fe^(3+) and Fe ` are kept together :

The standard potential (E^(0)) for the half reaction are as Zn to Zn^(2+) + 2e^(-) , E^(0) = + 0.76 V Fe to Fe^(2+) + 2e^(-) , E^(0) = + 0.41 V . The emf for the cell reaction Fe^(2+) + Zn to Zn^(2+) + Fe is

E^(@) for Fe^(2+) + 2e to Fe is -0.44 V , E^(@) for Zn^(2+) + 2e to Zn is - 0.76 V . Then

The standard reduction potentials at 298 K for the following half cell reactions are given below Zn^(2+) (aq) + 2e^(-) to Zn (s)-0.762 Cr^(3+) (aq) + 3e^(-) to Cr (s)-0.740 2H^(+) (aq) + 2e^(-) to H_(2) (g)-0.000 Fe^(3+) (aq) + e^(-) to Fe^(3+) (aq)-0.770 Which one is the strongest reducing agent?

Standard electrode potentials of Fe^(2+) + 2e to Fe and Fe^(3+) + 3e to Fe are -0.440V and -0.036V respectively. The standard electrode potential (E^@) for Fe^(3+) +e to Fe^(2+) is

Consider the following standard reduction potentials Fe^(3+)(aq) + e^(-) iff Fe^(3+) (aq) , E^(@) = 0.77 V , H_2O_2(aq) + 2e^(-) iff 2OH^(-)(aq) , E^(@) = 0.88 V For the voltaic cell reaction below , calculate the Fe^(2+) concentration ( in M) that would be needed to produce a cell potential equal to 0.16 V at 25^@ C when [OH^(-)] = 0.1 M , [Fe^(3+)] = 0.5 M and [H_2O_2]= 0.35M 2Fe^(2+)(aq) + H_2O_2(aq) iff 2Fe^(3+) (aq) + 2OH^(-) (aq)

The number of d-electrons retained in Fe^(2+) (At. no. of Fe = 26) ion is

For the reduction of NO_(3)^(-) ion in an aqueous solution , E^(0) is + 0.96 V , the values of E^(0) for some metal ions ar given below : i) V_((aq))^(+2) + 2e^(-) to V, E^(0) = 1.19V ii) Fe_((aq))^(+3) + 3e^(-) to Fe , E^(0) = -0.04 V iii) Au_((aq))^(+3) + 3e^(-) to Au , E^(0) = + 1.40 V iv) Hg_((aq))^(+2) + 2e^(-) to Hg , E^(0) = +0.86 V The pair(s) of metals that is/are oxidizd by NO_3^(-) in aqueous solution is /are