104 ACIDS AND BASES: OXIDATION AND REDUCTION
lor which AG = AG(7; + AG(%
= ( - 1467) + ( -f 1312)
- 155 kJ
Thus chloride ions are oxidised to chlorine by manganate(VII) under
standard conditions
(b) Cr 2 CH~(aq) + 6C1"(aq) + 14H 3 O + -> 2Cr^3 + (aq)
4- 21H 2 O -f 3Cl 2 (aq)
- 155 kJ
Reaction AG~* = -nh'c(i) Cr 2 O= (aq) + 6e + 14H 3 CT +1,33 jf} = ^6 x 96487 x (+1.33)
-> 2Cr^3 '(aq) + 21H 2 O "
k1 2 |aq) + f " -> CP(aq) +1.36
Cl'(aq) ->• K'Maq) + f' -1,36 -1 x 96 487 x ( - 1,36)
(ii) 6C1 (aq) ->~3Cl 2 (aq) + 6t>" -1.36 AG(T*» = -6 x 96487 x (-1,36)Hence (i) and (ii) give
6CP(aq)
21H 2 O + 3Cl 2 (aq)
for which AG - AGg -f
= ( -769)
= + 18 kJ( + 787)Thus under standard conditions chloride ions are not oxidised to
chlorine by dichromate(VI) ions. However, it is necessary to empha-
sise that changes in the concentration of the dichromate(VI) and
chloride ions alters their redox potentials as indicated by the Nernst
equation. Hence, when concentrated hydrochloric acid is added to
solid potassium dichromate and the mixture warmed, chlorine is
liberated.Equilibrium constants from electrode potentialsWe have seen that the energetic feasibility of a reaction can be
deduced from redox potential data. It is also possible to deduce the
theoretical equilibrium position for a reaction. In Chapter 3 we saw
that when AG = 0 the system is at equilibrium. Since AG = — nFE,
this means that the potential of the cell must be zero. Consider once
again the reaction
+ Zn(s) -* Cu(s) + Zn^2 f (aq)