\[{{\overset{0}{\mathop{Cl}}\,}_{2\left( g \right)}}+2OH_{\left( aq \right)}^{-}\to \]     \[\overset{+1}{\mathop{Cl}}\,{{O}^{-}}_{\left( aq \right)}+{{\overset{-1}{\mathop{C{{l}^{-}}}}\,}_{\left( aq \right)}}+{{H}_{2}}{{O}_{\left( l \right)}}\]
Chlorine is simultaneously reduced and oxidised.

$$\eqalign{ & KMn{O_4} \to + 1 + x - 8 = 0 \Rightarrow x = + 7 \cr & {K_2}Mn{O_4} \to + 2 + x - 8 = 0 \Rightarrow x = + 6 \cr & Mn{O_2} \to x - 4 = 0 \Rightarrow x = + 4 \cr & M{n_2}{O_3} \to 2x - 6 = 0 \Rightarrow x = + 3 \cr} $$

Fluorine is most electronegative element in the periodic table hence it does not show positive oxidation state.

In $$C{N^ - },$$  oxidation of $$C$$  is +2, and it changes to +4 oxidation state in $$C{O_2}.$$  So $$C$$  is also oxidised.

$$O = \mathop C\limits^{ + 2} = \mathop C\limits^0 = \mathop C\limits^{ + 2} = O$$
In $${C_3}{O_2},$$  two $$C$$ atoms linked with oxygen atoms are present in +2 oxidation state and central carbon has zero oxidation state. So, the average oxidation state of $$C$$ is $$ + \frac{4}{3}.$$

Oxidation state of $$N$$ varies from + 5 to - 3.

$$KMn{O_4}$$  is purple coloured and it changes its colour during titration, hence it is a self-indicator.

Disproportionation reaction is a special type of redox reaction in which an element in one oxidation state is simultaneously oxidised and reduced.

Oxidation number of $$Mo$$  in $${\left[ {M{o_2}{O_4}{{\left( {{C_2}{H_4}} \right)}_2}\left( {{H_2}{O_2}} \right)} \right]^{2 - }}$$
$$\eqalign{ & 2x + 4\left( { - 2} \right) + 0 + 0 = - 2 \cr & 2x - 8 = - 2 \Rightarrow x = + 3 \cr} $$

$$\eqalign{ & {\text{The balanced equation :}} \cr & 2\,N{H_3} + OC{l^ - } \to {N_2}{H_4} + C{l^ - } + {H_2}O \cr} $$