Given that
`NiO_(2)+4H^(+)+2e^(-)rarrNi^(2+)+2H_(2)O,E^(@)=1.678V`
`NiO_(2)+2H_(2)O+2e^(-)rarrNi(OH)rarrNi(OH)_(2)+2OH^(-)E^(@)=-0.49V`
For the following reaction
`Ni(Oh)_(2)+2H^(+) Ni^(2+)+2H_(2)O`
Gibb 's freee energy change in kl `mol^(-1)` is

The following reaction is a/an Ba(OH)_(2)+H_(2)SO_(4) to BaSO_(4)+2H_(2)O

H_(3)O^(+) + OH^(-) rarr 2H_(2)O is

H_(2)O_(2)rarr 2H^(+)+O_(2)+2e^(-),E^(@)=-0.68V . This equation represents which of the following behaviour of H_(2)O_(2)

The Edison storage cell is represented as, Fe_((s))|FeO_(S)||KOH_((aq.))||Ni_(2)O_(3(S))|No_((S)) the half-cell reactions are : Ni_(2)O_(3(S))+H_(2)O_((l))+2e^(-)rarr 2NiO_((S))+2OH^(-) , E^(@)=+0.40V FeO_((S))+H_(2)O_((I))+2e^(-)rarr Fe_((S))+2OH^(-) , E^(@)=-0.87V (i) What is the cell reaction ? (ii) What is the cell e.m.f. ? How does ir depend on the concentration of KOH ? (iii) What is the maximum amount of electrical energy that can be obtained from one mole of Ni_(2)O_(3) ?

MnO_(4)^(-) + 8H^(+) + 5e^(-) rightarrow Mn^(2+) + 4H_(2)O , E^(@) = 1.51V MnO_(2) + 4H^(+) + 2e^(-) righarrow Mn^(2+) + 2H_(2)O E^(@) = 1.23V E_(MnO_(4)^(-)|MnO_(2)