On the basis of the following `E^(@)` values, the strongest oxidising agent is
`[Fe(CN)_(6)]^(4-) to [Fe(CN)_(6)]^(3-)+e^(-),E^(@)-0.35V`
`Fe^(2+) to Fe^(3+),E^(@)=-0.77V`

On the basis of the following E^(@) values, the stongest oxidizing agent is [Fe(CN)_(6)]^(4-) rarr [Fe(CN)_(6)]^(3-)+e^(-), E^(@) = -0.35 V Fe^(2+) rarr Fe^(3+)+e^(-), E^(@) = -0.77 V

Fe(CN)_(2)darr+KCN to K_(3)Fe(CN)_(6)

K_(3)[Fe(CN)_(6)]+FeCl_(3) to Fe[Fe(CN)_(6)]darr

3KCN+Fe(CN)_(3)darr to K_(3)[Fe(CN)_(6)]

K_(3)[Fe(CN)_(6)]+FeCl_(2) to Fe_(3)[Fe(CN)_(6)]_(2)darr

Calculate magnetic moment of Fe^(3+) in [Fe(CN)_(6)]^(3+) and in [Fe(H_(2)O)_(6)]^(3+)

How would you account for the magnetic behaviour of [Fe(CN)_(6)]^(3-) and [Fe(CN)_(6)]^(4-) ?

With Co^(2+) ions [Fe(CN)_(6)]^(3-) gives a ……..ppt of Co_(3)[Fe(CN)_(6)]

The overall formation constant of the following reaction is 1 xx 10^(19) Co^(+2) +6CN^(-) Leftrightarrow [Co(CN)_(6)]^(-3) Calculate formation constant of following comples Co^(+3) +6CN^(-) Leftrightarrow[Co(CN)_(6)]^(-3) Given that [Co(CN)_(6)]^(-4) to [Co(CN)_(6)]^(-3) +e^(-), E^(0)=-0.83V Co^(+3) +e^(-) to Co^(+2), E^(0)=1.82 V

(i) On the basis of the standard electrode potential values stated for acid solutions, predict whether Ti^(4+) species may be used to oxidise Fe(II) to Fe(III) {:(Ti^(4+) + e^(-) to Ti^(3+), E^(@) = +0.01V), (Fe^(3+) + e^(-) to Fe^(2+), E^(@)= +0.77V):} (ii) Based on the data arrange Fe^(3+), Mn^(2+) " and " Cr^(2+) in the increasing order of stability of +2 oxidation state. (Give a brief reason) E_(Cr^(3+)//Cr^(2+))^(@) = -0.4V E_(Mn^(3+)//Mn^(2+))^(@) = +1.5V E_(Fe^(3+)//Fe^(2+))^(@) = +0.8V